THE ENCYCLOPEDIA OF VISUAL MEDICINE SERIES
An Atlas of
SCHIZOPHRENIA
Martin Stefan Fulbourn Hospital, Cambridge, UK
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THE ENCYCLOPEDIA OF VISUAL MEDICINE SERIES
An Atlas of
SCHIZOPHRENIA
Martin Stefan Fulbourn Hospital, Cambridge, UK
Mike Travis Institute of Psychiatry, De Crespigny Park, London, UK
and
Robin M. Murray Institute of Psychiatry, De Crespigny Park, London, UK
©2002 CRC Press LLC
Published in the UK and Europe by The Parthenon Publishing Group 23–25 Blades Court Deodar Road London, SW15 2NU, UK Published in the USA by The Parthenon Publishing Group 345 Park Avenue South, 10th Floor New York 10010, USA Copyright © 2002, The Parthenon Publishing Group Library of Congress Cataloging-in-Publication Data An atlas of schizophrenia / [edited by] Martin Stefan, Mike Travis and Robin M. Murray. p. ; cm. -- (Encyclopedia of visual medicine series) Includes bibliographical references and index. ISBN 1-85070-074-5 (alk. paper) 1. Schizophrenia -- Atlases. I. Stefan, Martin. II. Travis, Mike. III. Murray, Robin MD, MPhil, MRCP, MRCPsych. IV. Series. [DNLM: 1. Schizophrenia--Atlases. WM 17 A8813 2001] RC514 A86 2001 616.89’82--dc21 2001052033 British Library Cataloguing in Publication Data An atlas of schizophrenia. - (The encyclopedia of visual medicine series) 1. Schizophrenia I. Stefan, Martin II. Travis, Mike III. Murray, Robin, 1944616.8’982 ISBN 1859799745 No part of this book may be reproduced in any form without permission from the publishers except for the quotation of brief passages for the purposes of review Composition by The Parthenon Publishing Group, London, UK Color reproduction by Graphic Reproductions, Morecambe, UK Printed and bound by T. G. Hostench S. A., Spain
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Contents
Preface Foreword 1
Clinical features
2
Epidemiology and risk factors
3
Pathogenesis
4
Neurochemistry and pharmacotherapy
5
Psychosocial treatment
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Other atlases in this series include:
Epilepsy Parkinsons Disease Multiple Sclerosis Headache Stroke Depression Pain Prostatic Diseases Erectile Dysfunction Hair and Scalp Disorders Gastroenterology Sigmoidoscopy and cytoscopy Diabetes Uro-oncology
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Preface
There have been major changes in attitudes towards schizophrenia in recent years. In clinical practice, more effective pharmacological and psychological treatments for schizophrenia have helped regenerate a sense of therapeutic optimism. In research, progress in a range of basic disciplines has opened up new avenues which promise to help unravel the abnormalities of brain development, structure and function which are at the core of the disorder. These have been complimented by advances from epidemiology which remind us that schizophrenia is not just a brain disorder, and that social and psychological factors can have a profound impact on its onset and outcome. Research in schizophrenia has never been more exciting. This Atlas is our
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attempt to put together a visual overview of this fascinating and challenging territory. We have included many of the more familiar landmarks and monuments, but also some informative images of the most interesting new developments. Inevitably, because of the vast volume of new developments, our compilation has been somewhat selective. However, we hope this Atlas reflects our sense that a cohesive clinical and theoretical understanding of this complex disorder is now within reach, and that we can now bring hope and better care to sufferers. Martin Stefan, Mike Travis and Robin M. Murray November 2001
Foreword
Schizophrenia is a puzzle. Emil Kraepelin considered that his life's work had resulted merely in progress in understanding the psychoses, not a solution. Gottesman and Shields regarded the causes of schizophrenia as being an epigenetic puzzle, an analogy that continues to serve us well. Research in this area seems to produce ever more pieces, rather than fitting them together. More importantly, schizophrenia puzzles patients who have the syndrome, their families and, as often as not, the clinicians who try to help them. Martin Stefan, Mike Travis and Robin Murray are experts in this field, and have produced an excellent and highly readable overview of the clinical features of the disorder, the epidemiological context, possible causes, and the current status of drug treatment. Clinicians working in all aspects of services for people with schizophrenia will find this an accessible and clear reference. Many may consider recommending the book to some patients and carers who want
©2002 CRC Press LLC
rather more information than is contained in standard educational materials. An atlas is probably not the most obvious format for a book on schizophrenia but the authors have succeeded in producing a useful and interesting one. Diagrams, tables and figures give contemporary views an immediate impact, with modern techniques of investigation, such as neuroimaging, being particularly well suited to this format. These are balanced by the paintings from the Bethlem Royal Hospital Archives and Museum that entertain and fascinate alongside the factual information: they give an impression of the human as well as scientific and psychiatric aspects of schizophrenia. Thus, the book provides a useful map for all.
Peter Jones Professor of Psychiatry University of Cambridge
CHAPTER
1
Clinical features
HISTORY AND CLASSIFICATION Schizophrenia is arguably the most severe of the psychiatric disorders. It carries a lifetime risk of around 0.5–1%, and its early onset and tendency to chronicity mean that its prevalence is relatively high. Disability results particularly from negative symptoms and cognitive deficits, features that can have a greater impact on long-term functioning than the more dramatic delusions and hallucinations which often characterize relapses. The social and economic impact of the illness is enormous, and its impact on sufferers and their families can be devastating. Although descriptions of people who may have had schizophrenia-like illnesses can be found throughout history (Figure 1.1) the first Figure 1.1 Sketch to Illustrate the Passions: Agony – Raving Madness, by Richard Dadd (1854). In this painting, Richard Dadd (1817–1886) alludes to a pre-Kraeplinian distinction between ‘raving madness’ and ‘melancholic madness’. Dadd himself was a patient at the Bethlem (Bedlam) Hospital, England’s oldest mental hospital, and at Broadmoor, the hospital for the criminally insane. A Victorian painter best known for his fairy paintings, Dadd developed his illness at around the age of 25, when he become suspicious and preoccupied with religion, and developed delusions relating to the Egyptian god Assyris, beliefs that thoughts and commands which he had to obey were put into his head, and delusions that he was persecuted by the devil. At the age of 27, in response to these beliefs, he attacked and killed his father. He spent the rest of his life in institutional psychiatric care. Figure reproduced with kind permission of the Bethlem Royal Hospital Archives and Museum, Beckenham, Kent, UK
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comprehensive descriptions date from the beginning of the 18th century (Figures 1.2 and 1.3)1. The modern concept of schizophrenia was first formalized by the German psychiatrist Emil Kraepelin (Figure 1.4)2,3 at the turn of the 20th century. Kraepelin, who drew on contemporary accounts of syndromes such as catatonia and hebephrenia, was the first to distinguish between
Figure 1.2 Frontispiece from Illustrations of Madness (1810), by John Haslam1, which provides a vivid description of psychosis in an individual patient early in the industrial revolution. James Tilley Matthews was admitted to the Bethlem Hospital in 1797, after writing a threatening letter to a senior official in the British Admiralty. Haslam, who was Matthews’ doctor at the Bethlem, wrote his book as a rebuttal of claims made in court that Matthews was not insane. Matthews believed that a ‘gang of villains, profoundly skilled in pneumatic chemistry’ were assailing him: ‘while one of these villains is sucking out the brain of the person assailed, to extract his existing sentiments, another of the gang will force into his mind a train of ideas very different from the real subject of his thoughts’. He experienced many other unpleasant experiences, including ‘sudden death squeezing, stomach skinning, apoplexy making with the nutmeg grater, lengthening of the brain, thought making and laugh making’. Figure reproduced with kind permission of the Bethlem Royal Hospital Archives and Museum, Beckenham, Kent, UK
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Figure 1.3 Air-loom, by James Tilley Matthews, circa 1810. This plate is included in Haslam’s book1. It is Matthews’ own ‘diagram or plan of the cellar or place where the assassins rendezvous and work, showing their own and their apparatuses’ relative positions, as it has at all times appeared to me by the sympathetic perception’. As well as the ‘air-loom’, Matthews indicates the sources of various abnormal experiences: the voices of the King, Bill, the Middle Man, the Glove Woman, Augusta, Charlotte, St Archy, and assorted visitors, who are ‘not half so distinct as when they advance to the Loom Table, especially the Middle Position’, together with a ‘door into a back room where I have not the least perception of them beyond the said door’. Figure reproduced with kind permission of the Bethlem Royal Hospital Archives and Museum, Beckenham, Kent, UK
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Figure 1.4 Emil Kraepelin (1856–1926). The fifth edition of Kraepelin’s Textbook of Psychiatry2, published in 1896, articulated a distinction between acquired and constitutional pathology in mental illness. The sixth edition, published in 1899, distinguished between dementia praecox and manic depressive insanity
Figure 1.5 Eugen Bleuler (1857–1939). In 1911, Eugen Bleuler published his monograph entitled Dementia Praecox, or the Group of Schizophrenias, and argued that dementia praecox was not a single disease, was not inevitably associated with intellectual decline, and had as its fundamental basis disorders of affectivity, ambivalence, autism, attention and will. Other symptoms such as delusions, hallucinations, abnormal behavior and catatonia were conceptualized as secondary ‘accessory symptoms’
the two major poles of severe mental illness. He described one group of patients in whom the clinical picture was dominated by disordered mood and who followed a cyclical pattern of relapse and relative remission; he termed this ‘manic depressive insanity’. Others had a deteriorating illness characterized by florid onset, often in adolescence, with a prolonged course marked by profound social and functional disability. He called the latter ‘dementia praecox’, and saw it as ‘a single morbid process’, endogenous rather than acquired, starting in youth and with dementia as a common outcome. This concept has since been enormously influential in guiding our perception of the disorder, even though Kraepelin himself came to recognize many of its limitations: for example, the disease was not always confined to younger people, the progression to dementia was not inevitable and in some individuals a recovery would be seen4.
The Swiss psychiatrist Eugen Bleuler (Figure 1.5) coined the term ‘schizophrenia’ in 1911 and this rapidly displaced dementia praecox5. Unlike Kraepelin, who was strongly influenced by the successes of clinical pathology in the search for causative agents in diseases such as syphilis and tuberculosis, Bleuler thought of schizophrenia in psychological rather than neuropathological terms. For Bleuler, the florid but highly variable symptoms of psychosis, such as delusions and hallucinations, were secondary, ‘accessory’ phenomena. At the core of the illness, he believed, was a more generalized psychological deficit, characterised by a ‘loosening of associations’ in the form of language, by deficits in volition and attention, and by incongruity of affect, ambivalence and autism. Although intellectually compelling as a model of schizophrenia, Bleuler’s core symptoms were difficult to define reliably. In particular, the limits
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SCHNEIDER’S SYMPTOMS OF THE FIRST RANK
• Audible thoughts • Voices heard arguing • Voices heard commenting on one’s actions • The experience of influences playing on the body • Thought withdrawal and other interferences with thought • Diffusion of thought • Delusional perception Figure 1.6 Kurt Schneider. In 1959 he listed the 'first rank features' of schizophrenia. One of these symptoms, in the absence of organic disease, persistent affective disorder, or drug intoxication, was sufficient for a diagnosis of schizophrenia
of ‘simple schizophrenia’ (schizophrenia uncomplicated by ‘accessory’ symptoms) and ‘latent schizophrenia’ (people with odd personalities said to share some of the characteristics of the fullblown disorder) were difficult to define. This confusion was compounded by the clinical heterogeneity of schizophrenia, the lack of clear prognostic features and the failure to discover any definitive pathological abnormalities, and led to an expansion of the concept of schizophrenia to the extent that it became a vague synonym for severe mental illness with different meanings in different countries. This was especially the case in the USA, where Bleuler’s concepts held great sway, and in the former Soviet Union, where different models (incorporating, for example, anorexia nervosa sufferers and political dissenters) had developed. In Western Europe, where the Kraeplinian formulation remained dominant, diagnosis was more consistent, partly because the positive psychotic symptoms central to the Kraeplinian definition are more readily and reliably determined. In 19596, Kurt Schneider (Figure 1.6) set out a list of such symptoms, which would be most likely, in the absence of organic brain disease, to
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• Feelings, impulses and volitional acts experienced as the work or influence of others
lead to the diagnosis of schizophrenia. These ‘symptoms of the first rank’ were selected because they were relatively easily elicited and reliably identified, rather than because of any central theoretical importance; nevertheless, they were highly influential in determining diagnostic practice. The International Pilot Study of Schizophrenia7 (IPSS; Figure 1.7) which investigated the illness in several centers around the world, suggested a high degree of consistency in the clinical picture of schizophrenia when diagnosed using strict diagnostic rules. This appeared to hold true in rural and in urban areas, and both in Western European countries and in developing countries. The use of operationalized diagnostic rules in this, and in the earlier US/UK Diagnostic Project, greatly facilitated research into the epidemiology of the disorder. Since then, as a result of the development and use of operationalized definitions in the Diagnostic and Statistical Manual8 of Mental Disorders (DSM–IV) in the USA, and the International Classification of Diseases9 (ICD–10) worldwide, definitions of schizophrenia have been considerably narrowed.
Figure 1.7 Geographical variations in the incidence of schizophrenia, (a) broadly defined and (b) narrowly defined. These data from the International Pilot Study of Schizophrenia7 were taken as evidence that, particularly when narrow operational criteria are used, the incidence of schizophrenia is remarkably constant between countries. Although this was very influential when it was published, subsequent studies have demonstrated that the incidence does indeed vary, with higher rates found in those born or brought up in cities and in certain immigrant groups
GEOGRAPHICAL VARIATIONS IN INCIDENCE
(a) Broad definition Aarhus Chandigarh rural Chandigarh urban Dublin Honolulu Moscow Nagasaki Nottingham 0
10
20
30
40
50
40
50
Incidence (per 100 000) (b) Restrictive definition Aarhus Chandigarh rural Chandigarh urban Dublin Honolulu Moscow Nagasaki Nottingham 0
10
20
30
Incidence (per 100 000)
Although diagnosis still depends on the presence of combinations of symptoms and the course of illness, and diagnostic practice may vary to some extent from country to country, there is a core group of patients who fulfill all definitions and would be diagnosed as suffering from schizophrenia anywhere in the world (Figure 1.8).
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Both ICD–10 and DSM–IV identify a number of subtypes of schizophrenia. In clinical practice, a distinction is also often made between acute and chronic schizophrenia. A third way of thinking about the varied clinical picture seen in schizophrenia is in terms of syndromes (Figure 1.9). Unlike subtypes, syndromes do not
Figure 1.8 Despite the advent of a variety of operational definitions, categorical definitions of schizophrenia vary in their cut-off points on a theoretical continuum. However, there is substantial overlap between diagnostic systems and a significant proportion of patients fulfil criteria in all systems
THE SPECTRUM OF PSYCHOSIS
Affective psychosis
Non-affective psychosis
schizoaffective and non-affective psychosis Non-affective psychosis ICD schizophrenia
Excess women
Excess men DSM–III schizophrenia
DSM–III–R schizophrenia DSM–IV schizophrenia
Poor outcome
Good outcome
SYNDROMES OF SCHIZOPHRENIA
Positive thought disorder
Reality distortion
Disorganization
Social withdrawal Apathy Self-neglect Negative thought disorder
Delusions Hallucinations Passivity phenomena
Negative
Figure 1.9 Symptoms of schizophrenia appear to cluster into three syndromes: ‘positive’, or reality distortion, characterized by delusions and hallucinations; ‘negative’, consisting of the ‘deficit’ symptoms including ‘negative thought disorder’, such as poverty of speech and poverty of content of speech; and ‘disorganization’, in which ‘positive’ formal thought disorder, for example knight’s move thinking or loosening of associations are seen
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represent exclusive domains; any individual patient may have features of more than one syndrome. Initial syndromal studies distinguished between positive and negative symptoms, but more recent work using factor-analytic studies of associations between symptoms supports the existence of a third syndrome, characterized by positive thought disorder or ‘disorganization’. Thus, most clinicians would recognize the existence of psychotic symptom clusters in the following three domains: 1. Delusions and hallucinations, the so-called ‘positive’ symptoms. 2.
Positive thought disorder or ‘disorganization’.
3.
Social withdrawal, apathy, self-neglect, poverty of speech and of content of speech, and other broadly ‘negative’ symptoms.
CLINICAL PRESENTATION AND SYMPTOMATOLOGY As in the rest of medicine, reliable diagnosis depends on accurate history taking and clinical
examination. The family and personal history may offer important etiological clues. There may be a family history of schizophrenia, complications in pregnancy or birth, or a personal history of childhood problems. Recent studies, including the follow-up of the British 1946 birth cohort10, have suggested that children who later develop schizophrenia are more likely to have a history of developmental delay, as well as slightly lower IQ and educational achievements than other children (Figure 1.10). They are also more likely to have interpersonal and behavioral difficulties. Mothers may describe their premorbid personality as having shown emotional detachment; ‘preschizophrenic’ children may appear cold and aloof, avoiding play and engaging in solitary occupations. Some may be prone to temper tantrums, tend to avoid competition, have odd ideas and seek refuge in fantasy. These characteristics are also over-represented in the families of schizophrenics, although they do not reliably predict the development of schizophrenia.
FOLLOW-UP OF THE UK 1946 BIRTH COHORT
birth
16 years
Speech defects Solitary
Delayed motor milestones
Social anxiety
43 years
Schizophrenia (n = 30)
Cognitive decrement
Figure 1.10 Differences between children destined to develop schizophrenia as adults and the general population were found across a range of developmental domains. As with some other adult illnesses, the origins of schizophrenia may be found in early life. This figure illustrates the associations between adult-onset schizophrenia and childhood sociodemographic, neurodevelopmental, cognitive, and behavioral factors in a cohort of 5362 people born in one week in 1946. Thirty cases of schizophrenia arose between ages 16 and 43 years. Data with permission from Jones P, Rodgers B, Murray R, et al. Child development risk factors for adult schizophrenia in the British 1946 birth cohort. Lancet 1994;344:1398–1402
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DIFFERENTIAL DIAGNOSIS OF SCHIZOPHRENIA ‘Functional’ Schizotypal disorder Persistent delusional disorders Acute and transient psychotic disorders Schizoaffective disorders Induced delusional disorder Mania Other nonorganic psychotic disorders ‘Organic’ Drug/substance-induced psychosis (e.g. alcohol withdrawal, amphetamines, crack cocaine, LSD, cannabis, PCP, and also steroids, dopamine agonists and some heavy metals) Epilepsy – in particular, the fits of temporal lobe epilepsy may resemble an acute psychotic episode Tumors, either primary or secondary Stroke Early dementia Long-term sequelae of head injury Endocrine causes (e.g. Cushing’s disease; rarely hyper- and hypothyroidism) Infections (e.g. neurosyphilis)
encephalitis,
meningitis,
Multiple sclerosis Autoimmune disorders such as systemic lupus erythematosus (SLE) Metabolic disorders (e.g. hepatic failure, uremia, hypercalcemia, acute intermittent porphyria)
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HALLUCINATIONS Hallucinations are defined as false perceptions in the absence of a real external stimulus. They are perceived as having the same quality as real perceptions and are not usually subject to conscious manipulation. Hallucinations in schizophrenia may involve any of the sensory modalities. The most common are auditory hallucinations in the form of voices, which occur in 60–70% of patients diagnosed with schizophrenia. Although voices in the second person are most common, the characteristic ‘Schneiderian’ voices are in the third person and provide a running commentary on the patient’s actions, arguing about the patient or repeating the patient’s thoughts. Voices may be imperative, ordering the patient to harm himself or others. Visual hallucinations occur in about 10% of patients, but should make one suspicious of an organic disorder. Olfactory hallucinations are more common in temporal lobe epilepsy than schizophrenia, and tactile hallucinations are probably experienced more frequently than is reported by patients. No single type of hallucination is specific to schizophrenia, and the duration and intensity are probably most important diagnostically.
CATATONIC SYMPTOMS These mainly motor symptoms may occur in any form of schizophrenia but are particularly associated with the catatonic subtype Ambitendence Alternation between opposite movements. Echopraxia Automatic imitation of another person’s movements even when asked not to. Stereotypies Repeated regular fixed parts of movement (or speech) that are not goal directed, e.g. moving the arm backwards and outwards repeatedly while saying ‘but not for me’.
Negativism Motiveless resistance to instructions and attempts to be moved, or doing the opposite of what is asked. Posturing Adoption of inappropriate or bizarre bodily posture continuously for a substantial period of time. Waxy flexibility The patient’s limbs can be ‘molded’ into a position and remain fixed for long periods of time.
THOUGHT DISORDERS
DISORDERS OF THOUGHT POSSESSION
Usually a disorder of the form of thought, such that the speech is difficult to follow or incoherent and follows no logical sequence.
Disorders of thought possession in schizophrenia are sometimes called thought alienation. The patient has the experience that his thoughts are under the control of an outside agency or that others are participating in his thinking.
Knight’s move thinking (or derailment) occurs when the patient moves from one train of thought to another which has no apparent connection to the first – it takes its name from the chess piece that moves two steps forward and one to the side. A less severe form is called loosening of associations which merges into tangential thinking and loss of goal. Some patients may invent neologisms (new words), exhibit verbal stereotypy (repetition of a single word or phrase out of context), or use metonyms (ordinary words given a special personal meaning). Negative thought disorder includes poverty of speech (limited quantity of speech), and poverty of content of speech (limited meaning conveyed by speech).
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Thought insertion The patient believes that thoughts that are not his own are being put into his mind by an external agency. Thought withdrawal The patient believes that thoughts are being removed from his mind by an external agency. Thought broadcasting The patient believes that his thoughts are being ‘read’ by others, as if they were being broadcast. Thought blocking Involves a sudden interruption of the train of thought, before it is completed, leaving a ‘blank’. The patient suddenly stops talking and cannot recall what he has been saying or thinking.
DELUSIONS A delusion is a fixed, false personal belief held with absolute conviction despite all evidence to the contrary. The belief is outside the person’s normal culture or subculture and dominates their viewpoint and behavior. Delusions may be described in terms of their content (e.g. delusions of persecution or grandeur). They can be mood congruent (the content of delusion is appropriate to the mood of the patient), or mood incongruent. Delusions are described as systematized if they are united by a single theme. A primary delusion arises fully formed without any discernible connection with previous events (also called autochthonous delusions), e.g. “I woke up and knew that my daughter was the spawn of Satan and should die so that my son could be the new Messiah”. Secondary delusions can be understood in terms of other psychopathology, for example hallucinations: “The neighbors must have connected all the telephones in the building; that’s why I can hear them all the time”. The term delusional mood is slightly confusing in that it does not describe an abnormal belief, but refers to an ill-defined feeling that something strange and threatening is happening which may manifest as perplexity, uncertainty or anxiety. This may precede a primary delusion or a delusional perception, which involves a real perception occurring almost simultaneously with a delusional misinterpretation of that perception, e.g. “I saw the traffic lights change from red to green and knew that I was the rightful heir to the throne of England”. Overvalued ideas are unreasonable and sustained intense preoccupations maintained with a strong emotional investment but less than delusional intensity. The idea or belief held is demonstrably false and not usually held by persons from the same subculture.
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Delusions may be classified in terms of their content, for example delusions of... Persecution An outside person or force is in some way interfering with the sufferer’s life or wishes them harm, e.g. “The people upstairs are watching me by using satellites and have poisoned my food”. Reference The behavior of others, objects, or broadcasts on the television and radio have a special meaning or refer directly to the person, e.g. “A parcel came from Sun Alliance and the radio said that ‘the son of man is here’, on a Sunday, so I am the son of God”. Control The sensation of being the passive recipient of some controlling or interfering agent that is alien and external. This agent can control thoughts, feeling and actions (passivity experiences), e.g. “I feel as if my face is being pulled upwards and something is making me laugh when I’m sad”. Grandeur Exaggerated belief of one’s own power or importance, e.g. “I can lift mountains by moving my hands, I could destroy you!”. Nihilism Others, oneself, or the world does not exist or is about to cease to exist (often called Cotard’s syndrome), e.g. “The inside of my tummy has rotted away. I have no bowels”. Infidelity One’s partner is being unfaithful (also known as delusional jealousy or the Othello syndrome). Doubles A person known to the patient, most frequently their spouse, has been replaced by another (also known as Capgras’ syndrome or, confusingly, ‘illusion’ of doubles). Infatuation A particular person is in love with the patient (also known as erotomania or de Clerambault’s syndrome). Somatic Delusional belief pertaining to part of the person’s body, e.g. “My arms look like they’ve been melted and squashed into a mess”.
THE ACUTE ILLNESS The onset may be rapid, or slow and insidious. In the latter situation in particular, there may be a prolonged period of undiagnosed illness in which the affected person slowly becomes more withdrawn and introverted. They may develop unusual interests, particularly of a religious or philosophical kind, and drift away from family and friends. They may also begin to fail in their occupation or schoolwork. This process can take weeks to years but eventually, often with a
seemingly precipitating event, the symptoms of florid illness appear. The acute symptoms are variable but usually include delusions, hallucinations, abnormal thought processes and passivity experiences (Figures 1.11–1.16). In addition, there may be formal thought disorder, and flat or inappropriate affect. Abnormal motor signs, sometimes termed catatonic, used to be common but now are much less so in Western countries. At this stage of the illness, positive symptoms tend to dominate the clinical picture.
Figure 1.11 Castle of Bad Dreams, by Phyllis Jones, 1936. This picture “Served a double purpose, firstly to illustrate one of Grimm’s fairytales of ‘The foolish old woman’ and her wishes, and secondly to symbolize her own life”. It is tempting to speculate that it indicates a depressive component to her symptoms. Reproduced with kind permission of the Bethlem Royal Hospital Archives and Museum, Beckenham, Kent, UK
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Figure 1.13 Puppeteers, by Phyllis Jones, 1936. This patient was a talented artist, who was admitted to a psychiatric hospital at the age of 22 years complaining of hearing voices, and convinced her food was being poisoned. The clinical description suggests a florid psychotic illness, of acute onset, accompanied by severe affective disturbance. Reproduced with kind permission of the Bethlem Royal Hospital Archives and Museum, Beckenham, Kent, UK Figure 1.12 Grey self-portrait, by Bryan Charnley. This painting illustrates aspects of Charnley’s psychotic symptoms, including that of hearing voices. Reproduced with kind permission of the Bethlem Royal Hospital Archives and Museum, Beckenham, Kent, UK
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Figure 1.14 Cordron, by Gilbert Price. This patient was admitted at the age of 22 years. His extreme shyness and eccentric behavior culminated in his arrest for ‘suspicious’ conduct. Neologisms, elaborated into complex descriptive systems of pictures, chimneys and other objects, dominated his psychopathology. Reproduced with kind permission of the Bethlem Royal Hospital Archives and Museum, Beckenham, Kent, UK
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Figure 1.15 Cats, by Louis Wain (1860–1939). Wain was a British artist who became famous for his drawings of cats. He was a patient at the Bethlem Hospital in the 1920s. Paintings such as these, which are suggestive of disorganization, visual perceptual disturbances and abnormalities of affect, have been taken as illustrative of his psychological decline, although more recent scholarship suggests that they were not out of keeping with contemporary design practice. Reproduced with kind permission of the Bethlem Royal Hospital Archives and Museum, Beckenham, Kent, UK
THE CHRONIC ILLNESS NEGATIVE SYMPTOMS Eventually, even without treatment, the acute symptoms of schizophrenia usually resolve. Unfortunately this does not always mean that the patient will fully recover. Over 50% of patients diagnosed as suffering from schizophrenia will show evidence of a significant degree of negative symptomatology. Furthermore, in chronic schizophrenia, positive symptoms also frequently remain, although they tend not to predominate. Negative symptoms may also be seen in the acute episode, and their onset can often precede (as one form of ‘schizophrenic prodrome’) the development of typical positive symptoms. Negative symptoms are multifactorial in origin. Primary negative symptoms may be difficult to distinguish from those secondary to florid positive
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Poverty of speech Restriction in the amount of spontaneous speech and in the information contained in speech (alogia). Flattening of affect Restriction in the experience and expression of emotion. Anhedonia–asociality Inability to experience pleasure, few social contacts and social withdrawal. Avolition-apathy Reduced drive, energy and interest. Attentional impairment Inattentiveness at work and interview.
Figure 1.16 Broach shizophrene, by Bryan Charnley. Bryan Charnley illustrated the experience of psychosis in many striking artworks, including a series of self-portraits painted as he came off medication (see Figure 1.20). Reproduced with kind permission of the Bethlem Royal Hospital Archives and Museum, Beckenham, Kent, UK
psychotic symptomatology, while others may represent side-effects of antipsychotic drugs. It is often difficult to differentiate between the negative symptoms of schizophrenia and the symptoms of a depressive illness. Depression is common in schizophrenia, and often becomes evident as the acute episode resolves. True primary negative symptoms are often described as ‘deficit’ symptoms. Their frequency is markedly increased in chronic schizophrenia and is related to poor prognosis, poor response to antipsychotic drugs, poor premorbid adjustment, cognitive impairment and structural brain abnormalities (sometimes called ‘type 2’ schizophrenia). These symptoms are not easy to treat, are often very distressing to families and carers,
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and are the most important cause of long-term disability.
COURSE AND OUTCOME OF SCHIZOPHRENIA The in-patient psychiatric population has fallen dramatically since the 1950s in Western countries, when effective antipsychotic drug treatments first became available (Figure 1.17). However, the outcome of schizophrenia, even with treatment, remains variable (Figure 1.18 and Table 1.1)11–17. Longitudinally, the typical course of chronic schizophrenia is described in Figure 1.1918. Schizophrenia also carries a high mortality. Rates of suicide in follow-up studies vary from about 2%
Figure 1.17 There was a steady increase in the in-patient mental hospital population in England and Wales during the hundred years from 1860. This was due to a combination of factors, including increased urbanization and changes in mental health legislation. The sharp decline in this population coincided with the introduction of effective antipsychotic medication, together with changes in health policy and legislation
CHANGES IN THE IN-PATIENT PSYCHIATRIC POPULATION OF ENGLAND & WALES
Average annual occupied psychiatric hospital beds
160 000 140 000 120 000 100 000 80 000 60 000 40 000 20 000
18 4 18 5 5 18 5 65 18 7 18 5 8 18 5 9 19 5 0 19 5 1 19 5 2 19 5 3 19 5 4 19 5 5 19 5 6 19 5 7 19 5 8 19 5 95
0
FIVE-YEAR FOLLOW-UP OF 102 PATIENTS WITH SCHIZOPHRENIA
1
One episode no impairment.
13%
2
Several episodes with no or minimal impairment.
30%
Impairment after the first episode with occasional exacerbations of symptoms. No return to normality.
10%
Impairment increasing with each exacerbation of symptoms. No return to normality.
47%
3
4
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Figure 1.18 Course of schizophrenia. Four typical patterns in the course of schizophrenia are described by Shepherd and colleagues16 who followed up a cohort of patients with an operational (CATEGO-defined) diagnosis of schizophrenia who were admitted to a UK hospital over an 18-month period. Figure reproduced with permission from Shepherd M, Watt D, Falloon I, et al. The natural history of schizophrenia: a five-year follow-up study of outcome prediction in a representative sample of schizophrenics. Psychol Med Monogr 1989;15 (Suppl.):1–46
Table 1.1 Summary of long-term clinical outcome studies in schizophrenia. Table reproduced with permission from Frangou S, Murray RM. Schizophrenia. London: Martin Dunitz, 1997
Study Ciompi 198011,12
Years of follow-up
Number of patients
Good clinical outcome (%)
Poor clinical outcome (%)
Social recovery (%)
37
289
27
42
39
197813
23
208
20
24
51
Bland & Orne 197814
14
90
26
37
65
Salokangas 198315
8
161
26
24
69
Shepherd et al., 198916
5
49
22
35
45
Bleuler
to 10% and the overall rate of suicide in schizophrenia is estimated to be in the region of 10% (Figure 1.20).
COURSE OF SCHIZOPHRENIA (THEORETICAL MODEL)
FACTORS AFFECTING PROGNOSIS Certain clinical features are associated with a poor prognosis: early or insidious onset, male sex, negative symptoms19,20 (Figure 1.8), lack of a prominent affective component or clear precipitants, family history of schizophrenia, poor premorbid personality, low IQ, low social class, social isolation, and significant past psychiatric history. Several studies have demonstrated an association between longer duration of untreated illness and poorer outcome. For example, Loebel and colleagues21 found that a longer duration of both psychotic and prodromal symptoms prior to treatment was associated with a lesser likelihood of remission. The longer the duration of pretreatment psychotic symptoms, the longer the time to remission. These data suggest that early detection and intervention in schizophrenia may be important in minimizing subsequent disability.
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Course
Deteriorating 10
20
Stable 30
40
Improving 50
60
70
Years Figure 1.19 Breier and colleagues18 among others have suggested that, despite the heterogeneity of schizophrenia, a model of a common course of illness can be derived. Based on evidence from their own studies and other longterm follow-up studies they describe an earlier deteriorating phase usually lasting some 5 years. During this time there is a deterioration from premorbid levels of functioning, often characterized by frank psychotic relapses. After this phase much less fluctuation can be expected and the illness enters a ‘stabilization’ or ‘plateau’ phase. This period may continue into the fifth decade, when there is a third ‘improving’ phase for many patients. Figure reproduced with permission from Breier A, Schreiber JL, Dyer J, Pickar D. National Institute of Mental Health longitudinal study of chronic schizophrenia. Prognosis and predictors of outcome. Arch Gen Psychiatry 1991;48:239–46
Self-portrait 11–16 April 1991
April 20: ‘Very paranoid...The person upstairs is reading my mind and speaking back to me in a sort of ego crucifixion...The large rabbit ear is because I am confused and extremely sensitive to human voices, like a wild animal.’
April 29: Bryan has turmoil in his mind. The features in his portrait have become fragmented. He feels lonely and exposed, as on a stage. ‘A strange spiritual force is making me feel I should not smoke or I will incur a disaster.’
May 6: has turned himself into a dartboard. ‘I feel like a target for people’s cruel remarks. What is going on? I have sweet talked a girl to suicide because I had no tongue, no real tongue and could only flatter.’
May 18: acutely disturbed. ‘My mind seems to be thought-broadcasting very severely and it is beyond my will to do anything about it...I have summed this up by painting my brain as an enormous mouth.’
May 23: ‘The blue is there because I feel depressed, through cutting back on the antidepressants...the wavy lines are because just as I feel I am safe, a voice from the street guts me emotionally by its ESP of my conditions...I am so pleased that I have been able to express such a purely mental concept as thought-broadcasting by the simple device of turning the brain into a mouth.’
June 27 (left): This is Bryan’s most complex picture. He feels he is ‘closing in’ on the essential image of schizophrenia. He feels transparent. ‘I make crazy attempts at some sort of control over what has become an impossible situation (the man with the control stick). My brain, my ego is transfixed by nails as the Christ who could not move freely on the cross without severe pain. So I find I cannot think without feelings of pain.’ The red muzzled beast symbolizes silent anger. ‘My senses are being bent by fear into hallucinations.’
Figure 1.20 A series of self-portraits by Bryan Charnley which vividly illustrate his experiences as he came off medication. His descent into paranoia, hallucinations and depression is graphically depicted and explained with reference to his diary entries. Sadly the series ended with his death from suicide. Figures reproduced with kind permission of Mr Terence Charnley
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REFERENCES
12.
1. 2.
13.
3
4.
5.
6. 7.
8.
9.
10.
11.
Haslam J. Illustrations of Madness. London, 1810 Kraepelin E. Psychiatrie: Ein Lehruch fur Studierende und Arzte, 5th edn. Leipzig, Germany: JA Barth, 1896 Kraepelin E. Psychiatrie: Ein Lehruch fur Studierende und Arzte, 6th edn. Leipzig, Germany: JA Barth, 1899 Kraepelin E. Dementia Praecox and Paraphrenia [1919]. Robertson GM, ed; Barclay RM, trans. New York, NY: Robert E. Kreiger, 1971 Bleuler E. Dementia Praecox or the Group of Schizophrenias. Madison, CT: International Universities Press, 1950 Schneider K. Clinical Psychopathology. Hamilton MW, trans. London, UK: Grune and Stratton, 1959 World Health Organization. Report of the International Pilot Study of Schizophrenia. Geneva: WHO, 1979 American Psychiatric Association. Diagnostic and Statistical Manual, 4th Edition Revised (DSM–IV). Washington, DC: APA, 1994 World Health Organisation. The International Classification of Diseases, 10th Edition (ICD–10). Geneva: WHO, 1992 Jones P, Rodgers B, Murray R, et al. Child development risk factors for adult schizophrenia in the British 1946 birth cohort. Lancet 1994;344: 1398–1402 Ciompi L. Catamnestic long-term study of the course of life and aging in schizophrenia. Schizophr Bull 1980;6:606–18
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14. 15.
16.
17. 18.
19.
20.
21.
Ciompi L. The natural history of schizophrenia in the long term. Br J Psychiatry 1980;136:413–20 Bleuler M. The long-term course of schizophrenic psychoses. Psychol Med 1974;4:244–54 Bland RC, Orn H. 14-year outcome in early schizophrenia. Acta Psychiatr Scand 1978;58:327–38 Salokangas RK. Prognostic implications of the sex of schizophrenic patients. Br J Psychiatry 1983;142: 145–51 Shepherd M, Watt D, Falloon I, et al. The natural history of schizophrenia: a five-year follow-up study of outcome prediction in a representative sample of schizophrenics. Psychol Med Monogr 1989;15 (Suppl.):1–46 Frangou S, Murray RM. Schizophrenia. London: Martin Dunitz, 1997 Breier A, Schreiber JL, Dyer J, Pickar D. National Institute of Mental Health longitudinal study of chronic schizophrenia. Prognosis and predictors of outcome. Arch Gen Psychiatry 1991;48:239–46 Johnstone EC, Frith CD, Crow TJ, et al. The Northwick Park ‘Functional’ psychoses study: diagnosis and outcome. Psychol Med 1992;22:331–46 Johnstone EC, Crow TJ, Frith CD, Owens DG. The Northwick Park ‘Functional’ psychoses study: diagnosis and treatment response. Lancet 1988; 2:119–25 Loebel AD, Lieberman JA, Alvir JM, et al. Duration of psychosis and outcome in first-episode schizophrenia. Am J Psychiatry 1992;149:1183–8
CHAPTER
2
Epidemiology and risk factors
environmental risk factors (e.g. overcrowding, drug abuse) may also be operating. The onset of the disease is characteristically between the ages of 20 and 39 years, but may occur before puberty or be delayed until the seventh or eighth decade. The peak age of onset is 20–28 years for men and 26–32 years for women1 (Figure 2.2). The overall sex incidence is equal if broad diagnostic criteria are used, but there is some evidence for an excess in men if more stringent diagnostic criteria, weighted towards the more severe end of the diagnostic spectrum, are
The incidence of schizophrenia in industrialized countries is in the region of 10–70 new cases per 100000 population per year1, and the lifetime risk is 0.5–1%. The geographical distribution of schizophrenia is not random: recent studies have shown that there is an increased first-onset rate in people born or brought up in inner cities (Figure 2.1)2. There is also a significant socioeconomic gradient, with an increased prevalence in the lower socioeconomic classes. ‘Social drift’, both in social class, and into deprived areas of the inner cities, may account for part of this, but specific
Figure 2.1 Adjusted relative risk of schizophrenia in Denmark according to place of birth, with rural area used as the reference category (*). Data from reference 2
RELATIVE RISK OF SCHIZOPHRENIA ACCORDING TO PLACE OF BIRTH
Capital Suburb of capital Provincial city Provincial town Rural area* Greenland Other countries Unknown 0
1
2
3
4
5
Relative risk (95% Cl)
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6
7
Figure 2.2 This graph shows the incidence rate per 100 000 population for broadly defined schizophrenia in an inner city area of London (Camberwell). Although the overall rate is similar in males and females, mean onset in women is slightly later. Figure reproduced with permission from Castle E, Wessely S, Der G, Murray RM. The incidence of operationally defined schizophrenia in Camberwell 1965–84. Br J Psychiatry 1991;159:790–4
INCIDENCE OF SCHIZOPHRENIA BY GENDER
Rates per 100 000 population
60 Males Females
50 40 30 20 10 0 0–15
16–25
26–35
36–45
46–55
56–65
66–75
76+
Age at onset (years)
RELATIVE RISK OF SCHIZOPHRENIA ACCORDING TO MONTH OF BIRTH 1.4 1.3
Relative risk
1.2 1.1 1.0 0.9 0.8 0.7
Ja nu Fe ary br ua ry M ar ch A pr il M ay Ju ne Ju A ly u Se gu pt st em b O er ct o N be ov r em D be ec r em be r
0.6
Month of birth
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Figure 2.3 This graph is based on a population cohort of 1.75 million people from the civil registration system in Denmark. The data points and vertical bars show the relative risks and 95% confidence intervals, respectively, with the month of birth analyzed as a categorical variable. The curve shows the relative risk as a fitted sine function of the month of birth (the reference category is December). Figure reproduced with permission from Mortensen PB, Pedersen CB, Westergaard T, et al. Effects of family history and place and season of birth on the risk of schizophrenia. N Engl J Med
applied. The prevalence of schizophrenia is considerably higher in the unmarried of both sexes. There is a small excess of patients born during the late winter and early spring months in both northern and southern hemispheres (and a less wellknown decrement in late summer (Figure 2.3)2. People with schizophrenia have a twofold increase in age-standardized mortality rates, and are more likely to suffer from poor physical health. Much of the increased mortality occurs in the first few years after initial admission or diagnosis. Contributing factors early in the course include suicide, with later factors, such as cardiovascular disorders, due in part to the poor lifestyle of many patients, with heavy cigarette smoking and obesity being common.
THE RISK FACTOR MODEL OF SCHIZOPHRENIA It is often said that schizophrenia is a disease of unknown etiology. This is no longer true. Schizophrenia is like other complex disorders such as ischemic heart disease, which have no single cause but are subject to a number of factors that increase the risk of the disorder. Some of the risk factors for schizophrenia are summarized in Figure 2.4. Schizophrenia, however, differs from disorders such as ischemic heart disease in that we do not understand the pathogenic mechanisms linking the risk factors to the illness, i.e. we do not understand how the causes ‘cause’ schizophrenia.
THE DEVELOPMENTAL RISK FACTOR MODEL
Dysplastic networks Childhood vulnerability
Cognitive impairment Social difficulties
BIRTH
Early causes (genetic, obstetric complications)
ADOLESCENCE
Psychosis
Late causes (life events, drug abuse)
Figure 2.4 Causality over the life course. Risk factors for schizophrenia occur both early and late in the life course, and interact with each other in a complex fashion
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LIFETIME RISK OF DEVELOPING SCHIZOPHRENIA
General population Spouses of patient First cousins (third degree) Uncles, aunts Nephews, nieces Grandchildren Half siblings Children Siblings Siblings with one schizophrenic parent Dizygotic twins Parents Monozygotic twins Offspring of dual matings
Second-degree relatives
First-degree relatives
0
10
20
30
40
50
Lifetime risk of developing schizophrenia (%)
Figure 2.5 Lifetime risk of developing schizophrenia in relatives of schizophrenic individuals. Data from reference 3
CONCORDANCE RATES FOR SCHIZOPHRENIA FROM TWIN STUDIES Monozygotic
Study
Number of pairs
Dizygotic Number of pairs
Concordance rate (%) 45
Concordance rate (%)
Kringlen6
55
Fischer7 Shields & Gottesman4 Tienari8
21
56
41
22
58
33
12
20
13
Pollin et al.9
95
43
125
9
Cardno et al.10
49
41
57
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17
35
90
15 26
5
Figure 2.6 Concordance rates for schizophrenia in studies of monozygotic and dizygotic twins. The implication of the lack of 100% concordance in monozygotic twins is that there must be environmental etiological factors involved in the genesis of schizophrenia. Data from references 4–10
Relationship
Percentage schizophrenic
Parent
5.6
Sibling
10.1
Sibling and one parent affected
16.7
Children of one affected parent
12.8
Children of two affected parents
46.3
Uncles/aunts/nephews/nieces
2.8
Grandchildren
3.7
Unrelated
0.86
Table 2.1 Lifetime expectancy of broadly defined schizophrenia in the relatives of schizophrenics. Table reproduced with permission from Kendell RE, Zealley AK. Companion to Psychiatric Studies. Edinburgh: Churchill
GENETICS
Figure 2.7 A pair of monozygotic twins discordant for schizophrenia. The twin on the right has schizophrenia
The most important risk factor for schizophrenia is having an affected relative (Figure 2.5 and Table 2.1)3–5. Twin and adoption studies have been used to show that this is consequent upon genetic transmission. The consistently greater concordance in monozygotic (MZ) than dizygotic (DZ) twins4–10 (Figure 2.6) has been taken to indicate a genetic effect but does not prove this beyond doubt, since MZ twins may be treated more similarly by their parents (Figure 2.7). However, adoption studies have demonstrated conclusively that liability to schizophrenia is transmitted through genes and not through some intrafamilial environmental effect (Figure 2.8)11,12. Various models of genetic transmission of schizophrenia have been considered but found not to fit the data. There is no evidence to support the single major locus model, which implies that a gene of major effect causes schizophrenia but has incomplete penetrance or variable expression. The polygenic model implies that there are many contributing genes, while the multifactorial model
postulates that there are both genetic and environmental factors. The so-called multifactorial polygenic model involves an interaction between multiple loci and environmental factors, with schizophrenia being expressed only in individuals who exceed a certain threshold of liability. Although the mode of transmission has not been absolutely clarified, molecular and genetic epidemiological studies concur that it is most likely to involve a number of genes of small effect interacting with environmental factors, i.e. the multifactorial polygenic model. An alternative not yet excluded is the heterogeneity model, which proposes that schizophrenia consists of several distinct conditions, each with a distinct etiology. Molecular genetic studies have attempted to identify the particular genes that may be involved in the predisposition to schizophrenia. To date, no loci have been consistently replicated. This indicates that the susceptibility genes must each
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Figure 2.8 Studies of people with schizophrenia adopted away from home show conclusively that there is genetic liability to schizophrenia: there is an increase in the risk of schizophrenia associated with being a biological, but not an adoptive parent of an individual with schizophrenia. Data from references 11 and 12
ADOPTION STUDIES
No.
Study
Schizophrenia spectrum disorders (%)
Kety et al.11: Biological parents of schizophrenic adoptees Biological parents of control (normal) adoptees Adoptive parents of schizophrenic adoptees
12.1
66 65
6.2
63 68
Adoptive parents of control adoptees
1.6 4.4
Rosenthal et al.12: Children of schizophrenics adopted away
69
Children of normals adopted away
79
18.8 10.1
EXPOSURE TO OBSTETRIC COMPLICATIONS 30 Cases Controls
25
Frequency (%)
20
15
10
5
0 0
1
2
3
4
5
6
7
8
9
Number of obstetric complications
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10
11
Figure 2.9 Obstetric complications are more common in people with schizophrenia compared with controls. Patients with schizophrenia are especially likely to have suffered multiple complications
Figure 2.10 Obstetric complications are a risk factor for schizophrenia in patients with a younger age of onset; they do not seem to be involved in the etiology of late-onset schizophrenia. Those patients who suffered obstetric complications showed an earlier onset than patients who did not
OBSTETRIC COMPLICATIONS AND AGE OF ONSET
No obstetric complications Obstetric complications
Pollack and Greenberg, 199613 Pearlson et al., 198514 Owen et al., 198815 O'Callaghan et al., 199216 O'Callaghan et al., 199017
15
20
25
30
Mean age at onset of schizophrenia (years)
be of relatively small effect so as to have escaped detection. Much interest centers on so-called hotspots that may contain susceptibility genes on chromosomes 6, 8, 10, 13 and 22. There has also been interest in genes involved in the metabolism of dopamine and other catecholamines, and also in genes involved in the control of neurodevelopment.
ENVIRONMENTAL INFLUENCES There is no doubt that there is a heritable component to the etiology of schizophrenia. It is equally clear that genetic predisposition is not the whole story. Concordance in MZ twins is only about 50%; the rest of the variance must depend on the person’s environment. These are often split into early and late environmental factors (Figure 2.4).
Early environmental factors Obstetric complications
Large population-based studies have demonstrated that obstetric complications are more common in schizophrenic populations (Figure
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2.9). Meta-analyses show that exposure to obstetric complications roughly doubles the risk of later schizophrenia; however, this effect only operates for schizophrenic patients who present before the age of 25 years; obstetric complications are not involved in the etiology of late-onset schizophrenia (Figure 2.10)13–17. There has been a search to identify which particular obstetric complications are responsible. However, the evidence is that a range of prenatal and perinatal factors may be involved. Hypoxic ischemia has been particularly implicated; in the pre- or perinatal period this can lead to intraventricular or periventricular bleeds, resulting in ventricular enlargement; this might be one mechanism for ventriculomegaly in schizophrenia. Exocitotoxic damage associated with perinatal hypoxia may also account for some of the neurochemical abnormalities (e.g. of glutamatergic function) that are found. However, complications arising around the time of birth may reflect much earlier abnormal fetal development associated with defective genetic control of neurodevelopment and adverse environmental exposure (Figure 2.11)18.
ADVERSE PRENATAL ENVIRONMENTAL EXPOSURE AND INCIDENCE OF SCHIZOPHRENIA 5
Incidence (per 1000)
4 3 2 1
ar
M
Ja
n–
Fe b –A 194 M pr 4 ay 19 –J 44 Ju un l– 19 A Se ug 44 p– 1 O 94 4 c N ov t 19 44 –D e Ja c 1 n– 94 F 4 M eb ar 1 –A 94 M pr 5 ay 1 –J 94 Ju un 5 l– 19 A Se ug 45 p– 1 9 N Oct 45 ov 1 9 –D 45 e Ja c 1 n– 94 M Feb 5 ar –A 194 M pr 6 ay 19 –J 46 Ju un l– 19 A Se ug 46 p– 1 9 N Oct 46 ov –D 194 ec 6 19 46
0
Month of birth Figure 2.11 Exposure to nutritional deficiency during fetal development may be a risk factor for schizophrenia, as demonstrated by this study where the incidence of schizophrenia rose twofold in the group whose early fetal development occured between February and April 1945 – a period of severe famine in wartime Holland. Figure reproduced with permission from Susser E, Neugebauer R, Hoek HW, et al. Schizophrenia after prenatal famine: further evidence. Arch Gen Psychiatry 1996;53:25–31
Several studies have found men with schizophrenia to be at greater risk of obstetric complications and of preschizophrenic behavioral abnormalities, and male schizophrenics also have more marked structural brain changes. This may contribute to the fact that schizophrenia, tightly defined, is more common in men. It is also of earlier onset and greater severity, a pattern that is also seen in other neurodevelopmental disorders. Prenatal infection
Schizophrenia is more common among those born in the late winter and early spring (Figure 2.3), so one environmental stressor potentially affecting fetal brain development that has received considerable attention is in utero exposure to
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maternal infection in the cold winter months. There is some evidence to suggest that an increase in the number of births of individuals subsequently diagnosed as schizophrenic follows influenza epidemics, although both the existence and the importance of this effect remain controversial. Exposure in later pregnancy to several other viral infections, including rubella, has also been implicated in some studies. An increase in the rate of schizophrenia has also been described among those subjected to severe malnutrition during the third trimester in utero18. Further evidence for the importance of the uterine environment in the pathogenesis of schizophrenia comes from data suggesting that preschizophrenic babies have a smaller head circumference than controls, and from studies suggesting that schizophrenic
CANNABIS CONSUMPTION AT AGE 18 AND LATER RISK OF SCHIZOPHRENIA
30
Cases of schizophrenia (per 1000)
25 20 15 10 5 0
0
1
2–4
5–10
11–50
>50
Figure 2.12 Substance misuse can contribute to later development of schizophrenia. This study following army recruits found that those who admitted taking cannabis on more than 50 occasions had a sixfold risk of schizophrenia compared with non-users. Figure reproduced with permission from Andreasson S, Allebeck P, Engstrom A, Rydberg U. Cannabis and schizophrenia. A longitudinal study of Swedish conscripts. Lancet 1987;2:1483–6
Number of reported occasions
patients as a group may be of lower birth weight than the general population.
prefrontal nerve tracts and perforant pathway, or abnormal synaptic plasticity, may reveal earlier developmental abnormalities.
Neurodevelopmental abnormality
The morphological abnormalities that have been reported in schizophrenia are consistent with a neurodevelopmental event occurring in fetal or early development. Some believe that the onset of frank psychotic symptoms reflects the delayed sequelae of an earlier developmental aberration, which is then expressed as the brain continues to develop in adolescence and adult life – sometimes termed the ‘doomed from the womb’ view. Delayed emergence of abnormal behavior following lesions sustained during early development is a well recognized phenomenon, and is seen, for example, in animal models where ventral hippocampal lesions, initially ‘silent’, are followed by hyperactivity and increased responsiveness to stressful stimuli and to dopamine blockade as the animal matures. The inherited neurodevelopmental disease metachromatic leukodystrophy is more likely to be associated with schizophreniform symptoms if the clinical onset is in adolescence. In this case, as in schizophrenia, late maturational events, such as myelination of
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Later environmental factors Substance misuse
The relationship between substance misuse and schizophrenia is complex. Many drugs of abuse, such as ketamine, amphetamine, cocaine, and LSD, are psychotomimetic and can induce an acute schizophrenia-like psychosis. Psychoactive substance misuse both precedes and follows the onset of psychotic symptoms. Some patients state that they receive transient symptom relief and are using the drugs as a form of ‘self-medication’. However, it is also clear that abuse of certain drugs can increase the risk of schizophrenia. Evidence concerning cannabis comes from the Swedish army study19 in which army recruits were interviewed about their drug consumption and then followed-up for a decade and a half. Those who admitted taking cannabis on more than 50 occasions had a risk of later schizophrenia some six times that of non-abusers (Figure 2.12).
Figure 2.13 The rate of life events is increased in schizophrenia, although the effect is not as great as in depression. Figure reproduced with permission from Bebbington P, Wilkins S, Jones P, et al. Life events and psychosis. Initial results from the Camberwell Collaborative Psychosis Study. Br J Psychiatry 1993;162:72–9
FREQUENCY OF LIFE EVENTS
Life event rates per100 subjects
100 Schizophrenia Mania Depressive psychosis Controls
90 80 70 60 50 40 30 20 10 0 1
2
3
4
5
6
Months before onset/interview
It is estimated that 20–50% of the population with schizophrenia in Western countries may qualify as substance abusers or ‘dual-diagnosis’ patients. Such patients have a higher use of services and worse outcome than patients who are not abusers; they are more likely to be hospitalized and more likely to relapse. Patients with schizophrenia seem to be more vulnerable to significant harm at relatively lower levels of substance use. As substance misuse is so prevalent in the West, this is an area where secondary prevention of relapse could be focused. Social and psychological factors
Psychosocial factors appear to contribute to both the onset and the relapse of schizophrenia. The best documented are life events (Figure 2.13)20. The effect size is smaller than in depression and the time frame is somewhat shorter than in depression (where adverse life events are well
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recognized etiological factors), with the 3 weeks prior to onset seeming to be the most important. Unlike depression, all kinds of life events appear to be important, not just those involving loss. Many migrant groups show an increased firstinception rate of schizophrenia compared both to the population they have left and to that which they have joined. The most striking example of this is people of African-Caribbean origin living in the UK (Figure 2.14)1. It seems unlikely that the factors are biological. Odegaard21 suggested in 1933 that social isolation and alienation are the crucial factors, and most recent evidence points in this direction.
CONCLUSION There is no single cause for schizophrenia, rather a number of risk factors (Figure 2.15) interact to propel the individual over a threshold for expression of the disease.
ETHNICITY AND SCHIZOPHRENIA
60
Rate per 100 000 population
50
Figure 2.14 The differences in incidence in schizophrenia in people of African-Caribbean origin compared with those from other ethnic groups, in one study from Camberwell, South London. Figure reproduced with permission from Castle E, Wessely S, Der G, Murray RM. The incidence of operationally defined schizophrenia in Camberwell 1965–84. Br J Psychiatry 1991;159:790–4
40
30
20
10
0
All AfricanCaribbean
All other ethnic groups
RISK FACTORS AND EFFECT SIZES
Psychotic first-degree relative (RR = 10)
Obstetric complications Winter birth City birth / upbringing Cannabis use Member of certain immigrant groups Life events
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Figure 2.15 There is no single cause of schizophrenia. Instead, like other complex disorders such as coronary heart disease, a number of genetic and environmental factors interact to cause the disease
REFERENCES 1.
2.
3.
4.
5. 6.
7.
8.
9.
10.
11.
Castle E, Wessely S, Der G, Murray RM. The incidence of operationally defined schizophrenia in Camberwell 1965–84. Br J Psychiatry 1991;159: 790–4 Mortensen PB, Pedersen CB, Westergaard T, et al. Effects of family history and place and season of birth on the risk of schizophrenia. N Engl J Med 1999;340:603–8 Gottesman I, Irving I. Schizophrenia Genesis: The Origin of Madness. New York, Oxford: WH Freeman, 1991:203 Shields J, Gottesman II. Obstetric complications and twin studies of schizophrenia: clarifications and affirmations. Schizophr Bull 1977;3:351–4 Kendell RE, Zealley AK. Companion to Psychiatric Studies. Edinburgh: Churchill Livingstone, 1993 Kringlen E. Twin studies in schizophrenia with special emphasis on concordance figures. Am J Med Genet 2000;97:4–11 Fischer M. Genetic and environmental factors in schizophrenia. A study of schizophrenic twins and their families. Acta Psychiatr Scand 1973;238 (Suppl.):9–142 Tienari P, Sorri A, Lahti I, et al. Genetic and psychosocial factors in schizophrenia: the Finnish Adoptive Family Study. Schizophr Bull 1987;13: 477–84 Pollin W, Allen MG, Hoffer A, et al. Psychopathology in 15,909 pairs of veteran twins: evidence for a genetic factor in the pathogenesis of schizophrenia and its relative absence in psychoneurosis. Am J Psychiatry 1969;126:597–610 Cardno AG, Marshall EJ, Coid B, et al. Heritability estimates for psychotic disorders: the Maudsley twin psychosis series. Arch Gen Psychiatry 1999;56:162–8 Kety SS, Rosenthal D, Wender PH, Schulsinger F, et al. Mental illness in the biological and adoptive
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12.
13.
14.
15.
16.
17.
18.
19.
20.
21.
families of adopted schizophrenics. Am J Psychiatry 1971;128:302–6 Rosenthal D, Wender PH, Kety SS, et al. The adopted-away offspring of schizophrenics. Am J Psychiatry 1971;128:307–11 Pollack M, Woerner MG, Goodman W, Greenberg IM. Childhood development patterns of hospitalized adult schizophrenic and nonschizophrenic patients and their siblings. Am J Orthopsychiatry 1966;36: 510–7 Pearlson GD, Garbacz DJ, Moberg PJ, et al. Symptomatic, familial, perinatal, and social correlates of computerized axial tomography (CAT) changes in schizophrenics and bipolars. J Nerv Ment Dis 1985; 173:42–50 Owen MJ, Lewis SW, Murray RM. Obstetric complications and schizophrenia: a computed tomographic study. Psychol Med 1988;18:331–9 O'Callaghan E, Gibson T, Colohan HA, et al. Risk of schizophrenia in adults born after obstetric complications and their association with early onset of illness: a controlled study. Br Med J 1992;305: 1256–9 O'Callaghan E, Larkin C, Kinsella A, Waddington JL. Obstetric complications, the putative familialsporadic distinction, and tardive dyskinesia in schizophrenia. Br J Psychiatry 1990;157:578–84 Susser E, Neugebauer R, Hoek HW, et al. Schizophrenia after prenatal famine: further evidence. Arch Gen Psychiatry 1996;53:25–31 Andreasson S, Allebeck P, Engstrom A, Rydberg U. Cannabis and schizophrenia. A longitudinal study of Swedish conscripts. Lancet 1987;2:1483–6 Bebbington P, Wilkins S, Jones P, et al. Life events and psychosis. Initial results from the Camberwell Collaborative Psychosis Study. Br J Psychiatry 1993; 162:72–9 Odegaard S. Emigration and insanity. Acta Psychiatr Scand 1932;Suppl. 4
CHAPTER
3
Pathogenesis
Pathogenetic theories need to encompass all levels of brain structure and function, from the basic neuroanatomical level, through neurochemical, neurophysiological and neuropsychological findings, and thence through to symptoms. As yet, we have only a very partial understanding of these mechanisms.
a
STRUCTURAL IMAGING AND ANATOMICAL STUDIES The core brain structural finding in schizophrenia, of lateral ventricular enlargement (Figure 3.1) is now well established, but the degree of enlargement is relatively small (Figure 3.2); about 25% on average1. Monozygotic twins discordant for schizophrenia can be distinguished from their cotwins on the basis of ventriculomegaly and decreased temporal cortical volume (Figure 3.3)2. Numerous other morphological abnormalities have been reported (Figures 3.43 and 3.5). People with schizophrenia appear to have very slightly smaller brains with sulcal widening and reduced cortical volume, particularly in the temporal lobes. A number of other findings have been reported. Most of these are non-specific and tell us little about pathogenesis, but there are some clues to the processes that might be involved. Normally rare developmental abnormalities, such as agenesis of the corpus callosum (Figure 3.6), aqueduct stenosis, cavum septum pellucidum, cerebral
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b
Figure 3.1 Three-dimensional reconstruction of the ventricular system in schizophrenia. Structural changes appear in the shrunken hippocampus (yellow) and enlarged fluid-filled ventricles (gray) of the brain of a patient with schizophrenia (a) compared with that of a healthy volunteer (b). Figure reproduced with kind permission of Professor Nancy C. Andreasen, University of Iowa, USA
Figure 3.2 Mean ventricle : brain ratio (VBR) in controls and patients with schizophrenia from a total of 39 separate studies. The diagonal line indicates the line of equality. Thus, this figure demonstrates that no matter which diagnostic system or method of measuring brain volume is used, patients with schizophrenia do have larger ventricles than controls. Figure reproduced with permission from Van Horn JD, McManus IC. Ventricular enlargement in schizophrenia. A meta-analysis of studies of the ventricle : brain ration (VBR). Br J Psychiatry 1992;160:687–97
INCREASED VENTRICLE VOLUME IN SCHIZOPHRENIA
Schizophrenic mean VBR
12 10 8 6 4 2 Line of equality 0 0
2
4
6
8
10
12
Control mean VBR Diagnostic criteria and methods of measurement: Planimetry DSM–III RDC DSM–III/RDC WUC
Computerized DSM–III RDC DSM–III/RDC
Figure 3.3 Ventricular size in monozygotic twins discordant for schizophrenia. Coronal magnetic resonance images of twins discordant for schizophrenia show lateral ventricular enlargement in the affected twin. Figure reproduced with permission from Suddath RL, Christison GW, Torrey EF, et al. Anatomical abnormalities in the brains of monozygotic twins discordant for schizophrenia. N Engl J Med 1990;322:789–4
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COMPARATIVE MEAN VOLUMES OF BRAIN REGIONS IN SCHIZOPHRENIA
Ventricular structures Left lateral ventricle Right lateral ventricle Left frontal horn Right frontal horn Left body ventricle Right body ventricle Left occipital horn Right occipital horn Left temporal horn Right temporal horn Third ventricle Fourth ventricle Total ventricles Cortical/limbic structures Left hemisphere Right hemisphere Left frontal volume Right frontal volume Left temporal lobe Right temporal lobe Left amygdala Right amygdala Left hippocampus-amygdala Right hippocampus-amygdala Left hippocampus Right hippocampus Left parahippocampus Right parahippocampus Left superior temporal gyrus Right superior temporal gyrus Left anterior superior temporal gyrus Right anterior superior temporal gyrus Left posterior superior temporal gyrus Right posterior superior temporal gyrus Whole brain Subcortical structures Left caudate Right caudate Left putamen Right putamen Left globus pallidus Right globus pallidus Left thalamus Right thalamus Whole brain gray/white matter Gray matter White matter 80
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Comparative mean volume of subjects with schizophrenia (%)
Figure 3.4 Meta-analysis of absolute regional brain volumes in schizophrenic patients and controls, from a total of 58 studies. This figure shows how the mean volumes of different brain regions from people with schizophrenia differ from those of controls. Figure reproduced with permission from Wright IC, Rabe-Hesketh S, Woodruff PW, et al. Meta-analysis of regional brain volumes in schizophrenia. Am J Psychiatry 2000;157:16–25
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STRUCTURAL BRAIN ABNORMALITIES IN SCHIZOPHRENIA
Reduced brain volume Enlarged lateral ventricles Gyral abnormalities Abnormalities of white matter
Cortical cellular displacement
Reduced hippocampal volume
Blunted temporal horns of lateral ventricles
Figure 3.5 Some structural brain abnormalities possibly implicated in the pathogenesis of schizophrenia. Structural abnormalities have been described in many brain areas, and at a variety of anatomical levels, from gross macroscopic changes in whole brain volume, through to subtle cellular displacement or disorganization in the cortex. Increasingly, interest has focused on the distribution of abnormalities, and their structural connectivity: thus, white matter myelination, as well as cortical abnormalities, are targets of investigation
hamartomas and arteriovenous malformations occur with increased frequency in schizophrenia. At the cellular level, various abnormalities in cytoarchitecture have been reported in several brain regions, although not all of these findings have proved robust. However, evidence of neuronal displacement (Figure 3.7) suggests the possibility of some failure in neuronal migration, a process that occurs mainly during the second trimester of fetal development4. Several findings weigh against the most likely alternative of a neurodegenerative process. The balance of evidence is that most of the brain
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abnormalities seen in schizophrenia are present at first onset and are non-progressive. Furthermore, markers of neurodegeneration, such as proteins associated with glial response are largely absent, although there may be a small degree of periventricular gliosis. Extracerebral markers of abnormal fetal development provide indirect support for the idea that aberrant neurodevelopment is implicated in schizophrenia. Dermatoglyphic abnormalities are thought to reflect fetal maldevelopment and appear to be more common in schizophrenia (Figure 3.8). Minor physical anomalies also occur with greater frequency in
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Figure 3.6 Agenesis of the corpus callosum. This midline sagittal magnetic resonance image shows an absent corpus callosum, a dramatic example of a neurodevelopmental anomaly which, while extremely rare, is thought to have an increased incidence in people with schizophrenia
schizophrenic patients compared with normal controls.
FUNCTIONAL BRAIN IMAGING Functional brain imaging studies have used positron emission tomography (PET), single photon emission tomography (SPET) and, more recently, functional magnetic resonance imaging techniques (fMRI) to investigate regional cerebral blood flow (rCBF) and brain metabolism in schizophrenia (Figure 3.9)5. It was previously thought that a decrease in frontal blood flow and metabolism (‘hypofrontality’) was a constant feature of schizophrenia. However, this now appears to be a function of the cognitive load involved in the test that patients are carrying out at the time. For example, activation studies using ‘frontal’ tasks such as the Wisconsin
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8
Controls
Schizophrenics
Figure 3.7 These camera lucida drawings compare the distribution of nicotinamide-adenine dinucleotide phosphate-diaphorase-stained neurons (squares) in sections through the superior frontal gyrus of a control and schizophrenic brain. There is a significant shift in the direction of the white matter in the schizophrenic brain. Numbers 1 through 8 indicate compartments of the brain; Roman numerals indicate cortical layers. Figure reproduced with permission from Akbarian S, Bunney WE, Jr, Potkin SG, et al. Altered distribution of nicotinamideadenine dinucleotide phosphate-diaphorase cells in frontal lobe of schizophrenics implies disturbances of cortical development. Arch Gen Psychiatry 1993:50:169–77
card sorting test have shown that healthy volunteers increase blood flow to the dorsolateral prefrontal cortex during the task, while this is not apparent when schizophrenic patients perform the task. Other studies using verbal fluency as an activation task have found impaired frontal blood flow in schizophrenic patients (Figure 3.10)6. However, there are studies on both tasks that have
DERMATOGLYPHIC ABNORMALITIES IN SCHIZOPHRENIA
Absolute intrapair difference in total ridge count
60 50 40 30
Figure 3.8 Structural abnormalities may be found in schizophrenia outside the CNS; other structures that develop at the same time may also be involved. In monozygotic twins there should be little or no difference between the twins in total finger ridge count. It can be seen, however, that in twin pairs where one twin suffers from schizophrenia, there is a much greater difference in total finger ridge count. This is significant because finger ridges develop in the second trimester and therefore the differences illustrated in this slide may indicate a degree of maldevelopment in affected twins
20 10 0
Nonschizophrenic (n = 7)
Discordant for schizophrenia (n = 23)
Monozygotic twin pairs Pair discordant for depression
BASIS OF FUNCTIONAL MAGNETIC RESONANCE IMAGING
Neuronal activity
Increased local cerebral blood flow
Change in blood oxygenation
D Figure 3.9 Oxyhemoglobin and deoxyhemoglobin have slightly different magnetic properties, and this is used as the basis for the blood oxygenated level dependent (BOLD) method in functional magnetic resonance imaging (MRI). Increases in neuronal activity are accompanied by increases in regional cerebral blood flow, which exceed the increase in cerebral oxygen utilization. As a result the oxygen content of the venous blood is increased, leading to an increase in MRI signal intensity. Figure reproduced with permission from Longworth C, Honey G, Sharma T. Science, medicine, and the future. Functional magnetic resonance imaging in neuropsychiatry. Br Med J 1999;319:1551–4
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CONTROLS
PATIENTS WITH SCHIZOPHRENIA
Figure 3.10 Verbal fluency and frontal lobe blood flow in schizophrenia. Comparison using functional magnetic resonance imaging between five right-handed male schizophrenic patients and five matched controls performing a covert verbal fluency task. The schizophrenic patients showed a comparatively reduced response (red) in the left dorsal prefrontal cortex and inferior frontal gyrus, and an increased response (orange) in the medial parietal cortex. Figure reproduced with permission from Curtis VA, Bullmore ET, Brammer MJ, et al. Attenuated frontal activation during a verbal fluency task in patients with schizophrenia. Am J Psychiatry 1998; 155:1056–63
MOTOR ACTIVATIONS AT TWO POINTS IN TIME 4–6 WEEKS APART Normals at time 1 sagittal
Normals at time 2 sagittal
Schizophrenics at t1 sagittal
Schizophrenics at t2 sagittal
Sz t1–t2 sagittal
Figure 3.11 Hypofrontality in a motor activation task remitting with recovery from schizophrenic relapse. This study shows changes over time in neuronal response in a positron emission tomography study of willed action using a simple motor task. Prefrontal cortical activation not apparent at time 1 in the schizophrenic subjects (when they were acutely ill) becomes apparent at time 2, 4–6 weeks later. The figures show statistical parametric maps thresholded at p < 0.05, Bonferrroni corrected. Figure reproduced with permission from Spence SA, Hirsch SR, Brooks DJ, Grasby PM. Prefrontal cortext activity in people with schizophrenia and control subjects. Evidence from positron emission tomography for remission of ‘hypofrontality’ with recovery from acute schizophrenia. Br J Psychiatry 1998;172:316–23
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REGIONAL CEREBRAL BLOODFLOW (rCBF) AND SYNDROMES OF SCHIZOPHRENIA Psychomotor poverty syndrome
Disorganization syndrome
Reality distortion syndrome
Negative correlations
Positive correlations
Figure 3.12 Statistical parametric maps showing pixels in which there are significant correlations between rCBF and syndrome score, for the three syndromes of psychomotor poverty, disorganization and reality distortion. Different syndromes of schizophrenia may have different patterns of aberrant rCBF. Figure reproduced with permission from Liddle PF, Friston KJ, Frith CD, et al. Patterns of cerebral blood flow in schizophrenia. Br J Psychiatry 1992;160:179–86
not shown these differences between schizophrenics and controls. Although some studies have suggested that differences in rCBF between patients and controls are persistent, others have found that they appear to be state dependent, and remit with treatment (Figure 3.11)7. A number of studies have attempted to correlate patterns of brain activation with specific symptoms or syndromes of schizophrenia. Liddle and colleagues8 (Figure 3.12) investigated the three syndromes of psychomotor poverty, disorganization (i.e. inappropriate affect, speech content abnormalities), and reality distortion (i.e. delusions and hallucinations). They found that reduced rCBF in the left and medial prefrontal cortex correlated with psychomotor poverty; the severity of disorganization correlated with increased rCBF in the right medial prefrontal
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cortex and decreased perfusion in Broca’s area; and reality distortion correlated with increased rCBF in the left hippocampal formation. Studies of schizophrenic patients with and without auditory hallucinations have shown increased blood flow to Broca’s area when patients are hearing voices. Furthermore, patients prone to auditory hallucinations show abnormal patterns of blood flow when asked to imagine hearing voices, compared with normal controls (Figure 3.13)9, and patients with schizophrenia also appear to demonstrate abnormal patterns of temporal cortex activation in response to external speech. Abnormal patterns of blood flow also appear to be related to other specific symptoms of schizophrenia, including passivity phenomena (Figure 3.14)10 and formal thought disorder (Figure 3.15)11. Interest is focusing increasingly on the
SEROTONINERGIC PATHWAYS INNER SPEECH AND AUDITORY HALLUCINATIONS
0 mm
+60 mm
Figure 3.13 This study investigated the hypothesis that a predisposition to verbal hallucinations is associated with a failure to activate areas concerned with the monitoring of inner speech. Subjects, who included patients with schizophrenia both with and without a significant history of hallucinations, as well as normal controls, were asked to imagine sentences being spoken in another person’s voice. The figure illustrates positron emission tomography data superimposed on a normal magnetic resonance imaging scan, and shows reduced activation in the left middle temporal gyrus and the rostral part of the supplementary motor area in hallucinators compared to non-hallucinators. Similar findings were found in the comparison between schizophrenic patients and controls. Figure reproduced with permission from McGuire PK, Silbersweig DA, Wright I. Speech: a physiological basis for auditory hallucinations. Lancet 1995;346:596–600
RELATIVE HYPERACTIVATION IN PATIENTS WITH PASSIVITY
Compared with normals – free movement minus rest
Compared with other schizophrenic patients – free movement minus rest
Right inferior parietal lobule
–stereotypic movement minus rest
Compared with themselves at time 2 – free movement minus rest
–stereotypic movement minus rest
Figure 3.14 Positron emission tomography study of schizophrenic patients with passivity phenomena. This study looked at patients with schizophrenia who were also experiencing passivity phenomena (delusions of alien control) during a voluntary movement task. Hyperactivity is seen in these patients compared with normal controls (A), compared with other schizophrenic patients (B and C), and with themselves as their symptoms resolve (D and E). In each case, greater activation is seen in the right inferior parietal lobule (IPL), and at loci within the cingulate gyrus (CG). Figure reproduced with permission from Spence SA, Brookes DJ, Hirsch SR, et al. A PET study of voluntary movement in schizophrenic patients experiencing passivity phenomena (delusions of alien control). Brain 1997;120:1997–2011
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FUNCTIONAL IMAGING OF FORMAL THOUGHT DISORDER IN SCHIZOPHRENIA
Figure 3.15 PET data have been mapped onto a normal magnetic resonance image of a brain in standard stereotactic space, sectioned to provide transverse, coronal and sagittal views. The left side of the brain is shown on the left side of the image. The images show positive correlations between the severity of positive thought disorder and regional cerebral blood flow at the junction of the left parahippocampal and fusiform gyri (marked by cross hairs), and in the anterior part of the right fusiform gyrus. Figure reproduced with permission from McGuire PK, Quested DJ, Spence SA, et al. Pathophysiology of ‘positive’ thought disorder in schizophrenia. Br J Psychiatry 1998;173:231–5
patterns of correlation in brain activity between different brain areas, giving rise to the concept of functional dysconnectivity, the idea that there is impaired integration of cortical activity between different areas of the brain, rather than a specific focal abnormality or group of abnormalities.
people with schizophrenia and their relatives. Abnormalities in the auditory evoked potential have also been described, e.g. diminished amplitude and increased latency in the P300 response to an ‘oddball’ auditory stimulus, which appears to show both trait and state abnormalities (Figures 3.16 and 3.17)12.
NEUROCHEMISTRY The primary neurotransmitters implicated in the pathogenesis and treatment of schizophrenia are dopamine and serotonin. Recent theories have also implicated glutamine and γ−aminobutyric acid (GABA). The neurochemistry of schizophrenia is discussed fully in Chapter 4.
PSYCHOPHYSIOLOGY A crucial research problem in the etiology of schizophrenia is the difficulty in confidently defining a phenotype. One of the main goals of psychophysiological research in schizophrenia has been to identify trait markers that might identify people vulnerable to developing the disorder even if they are asymptomatic. Two promising trait markers have emerged. Eye tracking disorder, i.e. abnormalities of smooth pursuit eye movements, have been described in
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NEUROPSYCHOLOGY Various theories propose mechanisms that link abnormal neuropsychology in schizophrenia to its symptoms, and the functional neuroimaging techniques described above have begun to provide an important tool in beginning to unravel these relationships. For example, schizophrenic symptoms may arise from faulty attentional processes or ‘central monitoring’, and, as a result, the capacity to distinguish between internal and external stimuli may be impaired (leading, for example, to the experience of hallucinations). Disorders of volition, which are clearly important at the clinical level, may also have specific neuropsychological substrates. Understanding the relationships between symptoms, cognitive function and neurochemistry has become an important new goal in researching the mechanisms of drug action.
Figure 3.16 Abnormalities in evoked potentials have consistently shown abnormalities in schizophrenia. The P300 auditory event-related potential (ERP), seen here as one of several components of the auditory ERP, is seen as a response to ‘oddball’ or unexpected stimuli, and shows robust changes in both amplitude and latency in schizophrenic patients and their relatives.
AUDITORY EVENT-RELATED POTENTIALS
Amplitude
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Stimulus onset
P300 LATENCY IN SCHIZOPHRENIA
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Controls
+FH +FH relatives schizophrenics
Figure 3.17 These data suggest an increased P300 latency in patients with schizophrenia and their relatives when there is a strong family history of schizophrenia (+FH), but not in sporadic cases (–FH). P300 latency may be an important trait marker for the genetic vulnerability to schizophrenia. Figure reproduced with permission from Frangou S, Sharma T, Alarcon G, et al. The Maudsley Family Study, II: Endogenous event-related potentials in familial schizophrenia. Schizophr Res 1997;23:45–53
Figure 3.18 Deficits in premorbid IQ (as measured by the National Adult Reading Test) are seen in people with schizophrenia, but not in their first-degree relatives, or patients or relatives of patients with affective psychoses. The zero line is that of normal controls. Figure reproduced with permission from Gilvarry C, Takei N, Russell A, et al. Premorbid IQ in patients with functional psychosis and their first-degree relatives. Schizophr Res 2000;41:417–29
PREMORBID IQ IN PATIENTS WITH PSYCHOSIS AND THEIR RELATIVES 6 4 2
Premorbid IQ
0 –2 –4 –6 –8 –10 –12
Patients with Relatives of Patients with schizophrenia patients with affective schizophrenia psychoses
Relatives of patients with affective psychoses
NEUROPSYCHOLOGICAL PERFORMANCE IN SCHIZOPHRENIA
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Figure 3.19 Profile of neuropsychological performance of patients with schizophrenia. The deficits seen in schizophrenia are not uniform, but they encompass both executive function and memory. The zero line is the score of normal controls. Figure reproduced with permission from Bilder RM, Goldman RS, Robinson D, et al. Neuropsychology of firstepisode schizophrenia: initial characterization and clinical correlates. Am J Psychiatry 2 0 0 0 ; 1 5 7 : 549–59
The cognitive deficits seen in schizophrenia include lower premorbid IQ (Figure 3.18)13, as well as more circumscribed deficits, for example in memory and executive function (Figures 3.1914 and 3.2015). These are almost certainly a primary feature of the disorder. Some neuropsychological deficits are present long before the onset of schizophrenia. Two large cohort studies from the UK have supported the idea that the deficits of schizophrenia may be apparent early in life, with evidence of impaired educational test performance and avoidant social behavior (Figure 3.21)16. Childhood ‘schizoid’ personality traits may reflect deficits in cognition and in social behavior that are part of the disease process itself. Abnormalities of social behavior, movement and posture have also been reported (for example, in studies based on old home movies of affected and unaffected siblings). The antecedents of schizophrenia may therefore become identifiable long before the clinical onset of the illness.
SCORE ON WISCONSIN CARD SORT TEST
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Unaffected twin
Affected twin
Figure 3.20 Wisconsin card sort test (WCST) in monozygotic twins discordant for schizophrenia. The WCST is a measure of executive function. In twins discordant for schizophrenia, performance on the WCST is uniformly impaired in the affected twin. Data from Goldberg TE, Torrey EF, Bigelow LB, et al. Genetic risk of neuropsychological impairment in schizophrenia: a study of monozygotic twins discordant and concordant for the disorder. Schizophr Res 1995:17:77–84
Figure 3.21 The study of large birth cohorts provides a powerful tool for investigating risk factors in schizophrenia. In the 1946 UK birth cohort16, risk factors for later schizophrenia included problems at play, few friends, inappropriate emotional expression, anxiety, impaired intellectual function and odd movements. Figure reproduced with permission from Jones P, Rodgers B, Murray R, Marmot M. Child development risk factors for adult schizophrenia in the British 1946 birth cohort. Lancet 1994;344:1398–402
TRAJECTORY OF PREMORBID IMPAIRMENT
Deviance from controls
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Mean deviance
–5
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REFERENCES 1.
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7.
8.
Van Horn JD, McManus IC. Ventricular enlargement in schizophrenia. A meta-analysis of studies of the ventricle : brain ration (VBR). Br J Psychiatry 1992;160:687–97 Suddath RL, Christison GW, Torrey EF, et al. Anatomical abnormalities in the brains of monozygotic twins discordant for schizophrenia. N Engl J Med 1990;322:789–34 Wright IC, Rabe-Hesketh S, Woodruff PW, et al. Meta-analysis of regional brain volumes in schizophrenia. Am J Psychiatry 2000;157:16–25 Akbarian S, Bunney WE, Jr, Potkin SG, et al. Altered distribution of nicotinamide-adenine dinucleotide phosphate-diaphorase cells in frontal lobe of schizophrenics implies disturbances of cortical development. Arch Gen Psychiatry 1993:50:169–77 Longworth C, Honey G, Sharma T. Science, medicine, and the future. Functional magnetic resonance imaging in neuropsychiatry. Br Med J 1999;319:1551–4 Curtis VA, Bullmore ET, Brammer MJ, et al. Attenuated frontal activation during a verbal fluency task in patients with schizophrenia. Am J Psychiatry 1998;155:1056–63 Spence SA, Hirsch SR, Brooks DJ, Grasby PM. Prefrontal cortext activity in people with schizophrenia and control subjects. Evidence from positron emission tomography for remission of ‘hypofrontality’ with recovery from acute schizophrenia. Br J Psychiatry 1998;172:316–23 Liddle PF, Friston KJ, Frith CD, et al. Patterns of cerebral blood flow in schizophrenia. Br J Psychiatry 1992;160:179–86
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9.
10.
11.
12.
13.
14.
15.
16.
McGuire PK, Silbersweig DA, Wright I. Speech: a physiological basis for auditory hallucinations. Lancet 1995;346:596–600 Spence SA, Brookes DJ, Hirsch SR, et al. A PET study of voluntary movement in schizophrenic patients experiencing passivity phenomena (delusions of alien control). Brain 1997;120:1997–2011 McGuire PK, Quested DJ, Spence SA, et al. Pathophysiology of ‘positive’ thought disorder in schizophrenia. Br J Psychiatry 1998;173:231–5J Frangou S, Sharma T, Alarcon G, et al. The Maudsley Family Study, II: Endogenous event-related potentials in familial schizophrenia. Schizophr Res 1997; 23:45–53 Gilvarry C, Takei N, Russell A, et al. Premorbid IQ in patients with functional psychosis and their firstdegree relatives. Schizophr Res 2000;41:417–29 Bilder RM, Goldman RS, Robinson D, et al. Neuropsychology of first-episode schizophrenia: initial characterization and clinical correlates. Am J Psychiatry 2000;157:549–59 Goldberg TE, Torrey EF, Bigelow LB, et al. Genetic risk of neuropsychological impairment in schizophrenia: a study of monozygotic twins discordant and concordant for the disorder. Schizophr Res 1995: 17:77–84 Jones P, Rodgers B, Murray R, Marmot M. Child development risk factors for adult schizophrenia in the British 1946 birth cohort. Lancet 1994;344: 1398–402
CHAPTER 4 Neurochemistry and pharmacotherapy
INTRODUCTION
efficacy of typical antipsychotic (neuroleptic)
The discovery of the antipsychotic effects of chlorpromazine in the early 1950s heralded an era of effective pharmacological treatment for schizophrenia. Since the initial 1952 report of reduction in agitation, aggression and delusional states in schizophrenic patients, a wealth of placebo-controlled trials have established the
medication for acute schizophrenia, and for maintenance in chronic schizophrenia. Antipsychotics are therefore the mainstay of treatment in schizophrenia and knowledge of the chemistry and pharmacology of these medications has led to a greater understanding of the neurochemical basis of schizophrenia.
Table 4.1 The classification of antipsychotic drugs. The relevance of classifying antipsychotics according to their chemical class is seen when switching antipsychotics. Patients who do not respond to a medication coming from a particular chemical class should be switched to a medication of a different chemical class. The emphasis is now changing to pharmacological rather than chemical classes, as all of the newer medications belong to different chemical classes, but some share similar pharmacological properties
Type
Class
Examples
Typical antipsychotics
phenothiazines
chloropromazine, thioridazine trifluoperazine, fluphenazine haloperidol, droperidol flupenthixol, zuclopenthixol pimozide, fluspiraline
butyrophenones thioxanthenes diphenylbutylpiperidines Atypical antipsychotics
dibenzodiazepines benzixasoles thienobenzodiazepines dibenzothiazepines imidazolidinones benzothiazolylpiperazines substituted benzamides
quinolinones
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clozapine risperidone, iloperidone olanzapine quetiapine sertindole ziprasidone amisulpride, sulpiride (NB. sulpiride is considered by some to be a typical atipsychotic) aripiprazole
AFFINITY FOR DOPAMINE RECEPTORS AND CLINICAL POTENCY
IC50 (mol/l)
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Promazine Chlorpromazine Trazodone Clozapine Thioridazine Molindone Prochlorperazine Moperone Trifluperazine Thiothixene Haloperidol
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Range and average clinical dose for controlling schizophrenia (mg/day) Figure 4.1 Plot of the affinity of a wide variety of antipsychotic medications for the dopamine D2 receptor (y-axis), plotted against the average clinical daily dose used for controlling schizophrenia (x-axis), an estimate of clinical potency. As can be seen, there is a direct relationship between these two indices. This replicated finding contributed to the use of high-dose antipsychotics on the assumption that giving higher doses would make an antipsychotic more potent by ‘blocking’ more receptors
CLASSIFICATION OF ANTIPSYCHOTICS Antipsychotic drugs are not a homogeneous group, and there are various classes. The phenothiazines include chlorpromazine, trifluoperazine and fluphenazine. Other classes include the thioxanthenes (e.g. flupenthixol and zuclopenthixol) and the butyrophenones (e.g. haloperidol) (Table 4.1). The newer ‘atypical’ antipsychotics are mostly in different chemical classes, although they may share pharmacological characteristics.
NEUROCHEMISTRY OF SCHIZOPHRENIA AND MECHANISMS OF ACTION OF ANTIPSYCHOTICS Dopamine The observation from the early use of chlorpromazine that clinical improvement was often accompanied by a parkinsonism-like syndrome led
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to a focus on dopaminergic mechanisms of action for antipsychotics. In 1963 Carlsson and Lindqvist1 reported that antipsychotics increased turnover of brain dopamine, and suggested that this was in response to a functional ‘blockade’ of the dopaminergic system. Creese and colleagues2 demonstrated that the affinity of a wide range of antipsychotics to dopamine D2 receptors was proportionate to their clinical potency (Figure 4.1). Further evidence for the dopamine hypothesis is that amphetamines, which increase dopamine release, can induce a paranoid psychosis and exacerbate schizophrenia and that disulfiram inhibits dopamine hydroxylase and exacerbates schizophrenia3,4. Initial positron emission tomography (PET) studies of D2 receptor densities in drug-naive and drug-free patients with schizophrenia, using different tracers, were equivocal, with one group showing a marked increase in receptor density and
[123I]IBZM
SPET SCANS OF STRIATAL D2 RECEPTOR OCCUPANCY
Healthy volunteer
Clozapine treated patient with schizophrenia
Typical antipsychotic-treated patient with schizophrenia
High D2 receptor availability = no occupancy
Medium D2 receptor availability = medium (~60%) occupancy
Low D2 receptor availability = high (80%+) occupancy
Figure 4.2 Three single photon emission tomography (SPET), scans of striatal D2 and D2-like receptor availability at the level of the basal ganglia. In the scan on the left from a healthy volunteer there is no receptor occupancy and therefore 100% receptor availability for the binding of the D2 receptor tracer [123I]IBZM. The scan on the right is from a patient with schizophrenia receiving a typical antipsychotic. The bright areas from the left hand scan indicating high receptor density are not evident on the right-hand scan as the antipsychotic is occupying the majority of the receptors and preventing the tracer from binding. Unfortunately despite this high level of occupancy this patient has failed to respond to treatment. The central scan is from a patient receiving clozapine, although the striatum are not as ‘bright’ as in the healthy volunteer they are visible. This scan indicates intermediate occupancy of the receptors by clozapine. Importantly the patient with the intermediate occupancy has responded to treatment. Studies such as this one, when performed in larger groups, indicate that the simple dopamine hypothesis suggested by the data in Figure 4.1 needed refining. Figure reproduced with permission from Pilowsky LS, Costa DC, Ell PJ, et al. Clozapine, single photon emission tomography, and the D2 dopamine receptor blockade hypothesis of schizophrenia. Lancet 1992;340:199–202
another showing no change5. Although the majority of subsequent studies with PET or SPET have found no significant difference in striatal D2 receptor density between controls and patients with schizophrenia, in a recent meta-analysis of studies carried out between 1986 and 1997, a small but significant elevation of D2 receptors was noted in patients with schizophrenia5. However, the variability of D2 receptor density is high both in controls and patients with schizophrenia, and it has been argued that the small magnitude of the effect (approximately a 12% increase), and the possibility that any change reflects alteration in the baseline synaptic dopamine, means that there are no real functional differences in the density of striatal D2 receptors in schizophrenia (reviewed in reference 5).
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Despite these equivocal findings in drug-naive patients, emission tomography has reinforced the accepted theory that antipsychotic efficacy is related to D2, with 65% blockade a putative threshold for antipsychotic response6. Nonetheless, the situation appears very complex in that non-responders to antipsychotics still show high levels of striatal D2 blockade7,8. Furthermore, the highly effective atypical antipsychotic clozapine produces far less striatal D2 blockade than typical antipsychotics7–9, often below the putative 65% threshold (Figure 4.2). These findings have yet to be fully explained. Extrapyramidal side-effects (EPS) have also been studied and a threshold of 80% D2 occupancy has been repeatedly shown to be necessary to produce EPS6 (Figure 4.3). It may be that high levels of 5-HT2A receptor blockade, as seen with
100%
ineffective No EPS
Clinical effect
% Striatal D2 Receptor Occupancy
RELATIONSHIP BETWEEN D2 RECEPTOR OCCUPANCY EPS AND RESPONSE
50%
potentially effective & No EPS potentially effective but high EPS risk
0
Dose of antipsychotic Figure 4.3 Illustration of the relationship between clinical effectiveness, extrapyramidal sideeffects (EPS) and D2 receptor occupancy. With the exception of clozapine-induced D2 occupancy, below 60% striatal D2 occupancy produced by an antipsychotic medication is likely to be associated with treatment non-response, whilst occupancies above 80% are likely to be associated with a high risk of EPS. Once a patient is receiving a dose of an antipsychotic likely to be producing an occupancy between 60% and 80% there is little to be gained, in terms of treatment response, by increasing the dose of the antipsychotic further as the patient will almost certainly develop EPS. Figure after references 6, 7 and 51
DOPAMINE RELEASE BY AMPHETAMINE
[1231]IBZM displacement by amphetamine (% baseline)
50
40
30
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Schizophrenics p < 0.001
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Figure 4.4 The effect of amphetamine (0.3 mg/kg) on [123I]IBZM binding in healthy control subjects and untreated patients with schizophrenia. [123I]IBZM is a tracer for D2 receptors which allows in vivo measurement of D2 receptor availability (or binding potential) in humans using single photon emission tomography (SPET). The y-axis shows the percentage decrease in [123I]IBZM binding potential induced by amphetamine, which is a measure of the increased occupancy of D2 receptors by dopamine following the challenge. Thus, these results indicate that, when challenged with amphetamine, patients with schizophrenia release more dopamine than do healthy controls. Figure reproduced with permission from Laruelle M, Abi-Dargham A, Gil R, et al. Increased dopamine transmission in schizophrenia: relationship to illness phases [Review]. Biol Psychiatry 1999; 46:56–72
CLASSIFICATION OF DOPAMINE RECEPTORS
Dopamine
D2 receptor family
D1 receptor family
D1
D5
D2
D3
D4
Caudateputamen N. accumbens Olfactory tubercule
Hippocampus Hypothalamus
Caudateputamen N. accumbens Olfactory tubercule
Olfactory tubercule Hypothalamus N. accumbens Cerebellum
Frontal cortex Medulla Midbrain
Figure 4.5 There are currently five types of dopamine receptor identified in the human nervous system, D1 to D5. D1 and D5 receptors are similar in that they both stimulate the formation of cAMP by activation of a stimulatory G-coupled protein. D1 and D5 are therefore known as D1-like receptors. D2 to D4 receptors activate an inhibitory G-protein, thereby inhibiting the formation of cAMP. They are collectively known as D2-like receptors. D2 receptors are more ubiquitous than D3 or D4 receptors. D3 receptors are differentially situated in the nucleus accumbens (one of the septal nuclei in the limbic system) and D4 receptors are especially concentrated in the frontal cortex
most of the newer antipsychotics, may be protective against EPS by altering this threshold (reviewed in reference 10). Recent neurochemical imaging studies have indicated that people with schizophrenia have an increased sensitivity of their dopaminergic neurones to amphetamine challenge11 (Figure 4.4). Thus, it may be that in response to ‘stress’ such people will over-release dopamine and this may drive psychosis. There are currently five types of dopamine receptors identified in the human nervous system: D1 to D5. D1 and D5 receptors are similar in that they both stimulate the formation of cAMP by activation of a stimulatory G-coupled protein. D2 to D4 receptors act by activating an inhibitory Gprotein, thereby inhibiting the formation of cAMP. D2 receptors are more ubiquitous than D3 or D4 receptors. D3 receptors are differentially
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situated in the nucleus accumbens (one of the septal nuclei in the limbic system) and D4 receptors are especially concentrated in the frontal cortex (Figure 4.5). There are a number of different dopaminergic pathways or tracts (Figure 4.6). The nigrostriatal tract projects from the substantia nigra in the midbrain to the corpus striatum. This tract primarily has a role in motor control, although the ventral striatum has a role in reward- and goal-directed behaviors. Degeneration of the cells in the substantia nigra leads to idiopathic Parkinson’s disease, and it is by blocking the dopamine receptor at the termination of this pathway that the parkinsonian side-effects of classical antipsychotics arise. The mesolimbic/ mesocortical tract has its cell bodies in the ventral tegmental area adjacent to the substantia nigra. This tract projects to the limbic system and neocortex in addition to the striatum. This
THE DOPAMINERGIC PATHWAYS
G
E
F
A
D C
B
A B C D E
Substantia nigra Ventral tegmental area To amygdala Tuberoinfundibular DA system Nucleus accumbens (ventral striatum) F To the striatum (caudate nucleus, putamen and globus pallidus) G Frontal cortex
Figure 4.6 Representation of the primary dopamine-containing tracts in the human brain. The nigrostriatal tract is primarily involved in motor control, but also in reward- and goal-directed behavior. Blockade of D2 receptors here produces some of the antipsychotic effects of antipsychotics, but high levels of blockade (> 80%) produce parkinsonian side-effects. Blockade of D2 receptors in the tuberoinfundibular pathway increases plasma prolactin. It is thought that it is the blockade of D2 and D2-like receptors in the mesolimbic and mesocortical tracts that underlies the primary antipsychotic effects of all currently available antipsychotics
dopaminergic innervation supplies fibers to the medial surface of the frontal lobes and to the parahippocampus and cingulate cortex, the latter two being part of the limbic system. Because of this anatomic representation it is thought that this tract is where antipsychotic medication exerts its beneficial effect. The third major pathway is termed the tuberoinfundibular tract. The cell
62
bodies for this tract reside in the arcuate nucleus and periventricular area of the hypothalamus. They project to the infundibulum and the anterior pituitary. Dopamine acts within this tract to inhibit the release of prolactin. The blockade of these receptors by antipsychotics removes the inhibitory drive from prolactin release and leads to prolactinemia.
DOPAMINE SYNTHESIS
Phenylalanine
Tyrosine tyrosine hydroxylase (pterin cofactor)
Rate limiting step
Dopa
H C H
CH
H C H
CH
HO
HO Dopamine Dopamine ȋ-hydroxylase (copper containing enzyme) Ascorbate and O 2 required
CH
HO
HO
Dopa decarboxylase (pyridoxal cofactor)
H C H
NH 2
Figure 4.7 Dopamine is synthesized in a common pathway with norepinephrine. In the pathway shown, tyrosine hydroxylase is the rate-limiting enzyme. Dopamine β-hydroxylase is only found in noradrenaline neurons in the CNS
COOH
NH 2
COOH
NH 2
COOH H C H
CH 2
NH 2
H C CH 2 OH
NH 2
HO
HO Norepinephrine HO
Figure 4.8 Dopamine is metabolized by two enzymes. One, monoamine oxidase type B (MAO-B), is intraneuronal, and the other, catechol-O-methyl transferase (COMT), is extraneuronal. The primary metabolite of dopamine is homovanillic acid
DOPAMINE METABOLISM
Dopamine is synthesized as part of the common pathway for catecholamines (Figure 4.7). Dopamine is metabolized by two enzymes; one, monoamine oxidase type B (MAO-B), is intraneuronal, and the other, catechol-O-methyl transferase (COMT), is extraneuronal. The primary metabolite of dopamine is homovanillic acid (HVA; Figure 4.8).
Serotonin The serotonergic hypothesis of schizophrenia predates the dopaminergic hypothesis and stems from the finding by Woolley and Shaw in 195412 that the hallucinogen LSD acted via serotonin.
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Dopamine
Extraneural
Catechol-O-methyl transferase (COMT)
Intraneural
Monoamine oxidase type B (MAO-B)
Homovanillic acid (HVA)
SPET SCANS OF 5-HT2A RECEPTOR DENSITY
255 248
Temporal cortex and cerebellum
208 180
127
Frontal, parietal and occipital cortices
102 94
Healthy volunteer
Clozapine treated
Risperidone treated
Figure 4.9 Single photon emission tomography (SPET) scans of 5-HT2A receptor density in a healthy volunteer and two patients with schizophrenia receiving a therapeutic dose of either clozapine (450 mg/day) or risperidone (6 mg/day). In the slice at the level of the frontal, parietal and occipital cortices from the healthy volunteer the ubiquitous distribution of 5-HT2A receptors in the cortical gray matter can be seen. This binding of the tracer is absent from the equivalent slices from the medicated patients. This indicates that both clozapine and risperidone are producing very high or ‘saturation’ levels of 5HT2A receptor blockade. This high level of blockade may confer some protection against the development of EPS and may be one of the mechanisms of antipsychotic ‘atypicality’. Figure reproduced with permission from Travis MJ, Busatto GF, Pilowsky LS, et al. 5-HT2A receptor blockade in patients with schizophrenia treated with risperidone or clozapine. A SPET study using the novel 5-HT2A ligand 123I-5-I-R-91150. Br J Psychiatry 1998;173:236–41
There is a neuroanatomical and functional interaction of 5-HT and dopaminergic systems such that blocking 5-HT2A receptors enhances dopaminergic transmission. The newer atypical antipsychotics, in contrast with the typical antipsychotics, all have a higher affinity for the 5-HT2A receptor than for the D2 receptor. In terms of treatment response, there is a correlation of serotonergic neuroendocrine responses with symptomatic improvement on clozapine and preliminary data suggesting that allelic variations in the 5-HT2A receptor gene vary with, and may predict, treatment response10. PET studies of 5-HT2A receptor density in drug-naive patients with schizophrenia have failed to show any difference in comparison with
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matched healthy controls13,14. Previous studies with PET and SPET have indicated that the ‘atypical’ and newer antipsychotic medications like clozapine, risperidone, olanzapine and sertindole all lead to almost complete occupancy of cortical 5-HT2A receptors at clinically relevant doses15–17 (Figure 4.9) Full characterization of the effects of the older typical antipsychotics on 5-HT2A receptors remains to be completed, however, preliminary data indicates that broadspectrum typical antipsychotics such as phenothiazines and thioxanthines also lead to a significant occupancy (or reduction in receptor availability) of cortical 5-HT2A receptors, but the level of occupancy is still significantly lower than that seen with the newer medications18.
SEROTONINERGIC PATHWAYS
F G H
E I D A B C D E F G H I
Caudal raphe nuclei Rostral raphe nuclei Deep cerebellar nuclei Limbic structures Thalamus Neocortex Cingulum Cingulate gyrus To hippocampus
B
C
A
Figure 4.10 Representation of the primary serotonin-containing tracts in the human brain. Arising from the raphe nuclei these cells project to all cortical gray matter, with additional tracts to the basal ganglia and the cerebellum
More than nine distinct serotonin (5-HT) receptors have been identified. The 5-HT1A, 5HT2A, 5-HT2C, and 5-HT3 receptors have been most extensively studied. The major site of serotonergic cell bodies is in the area of the upper pons and midbrain. The classic areas for 5-HTcontaining neurons are the median and dorsal raphe nuclei. The neurons from the raphe nuclei project to the basal ganglia and various parts of the
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limbic system, and have a wide distribution throughout the cerebral cortices in addition to cerebellar connections (Figure 4.10). All the 5-HT receptors identified to date are G-protein coupled receptors, except the 5-HT3 receptor, which is a ligand gated Na+/K+ channel. 5-HT is synthesized from tryptophan by tryptophan hydroxylase, and the supply of tryptophan is the rate-limiting step in the
SEROTONIN SYNTHESIS AND METABOLISM
COOH CH 2CH
Tryptophan N H
Tryptophan hydroxylase
HO
COOH CH 2CH
5-Hydroxytryptophan N H
L-aromatic acid decarboxylase
NH 2
Figure 4.11 The rate-limiting step for serotonin synthesis is the availability of the precursor tryptophan. Tryptophan hydroxylase is the rate limiting enzyme. Serotonin in the CNS is primarily metabolized by monoamine oxidase. The primary metabolite is 5hydroxyindoleacetic acid
HO
NH 2
CH 2CH2NH2
Serotonin (5-HT) N H
Monoamine oxidase
HO
CH 2CHO N H
Aldehyde dehydrogenase
HO
CH 2COOH
5-Hydroxyindoleacetic acid (5-HIAA) N H
synthesis of 5-HT (Figure 4.11). 5-HT is primarily broken down by monoamine oxidase and the primary metabolite is 5-HIAA.
Other neurotransmitters Recent efforts have been directed towards finding an alternative neurochemical target in schizophrenia. The first of these that should be considered is gamma aminobutyric acid (GABA). GABA appears to have a regulatory role on dopaminergic function. The balance of evidence tends to suggest that GABA decreases dopaminergic firing. This links with human postmortem data indicating that GABAergic reductions correlate with increased dopamine concentrations19,20. Thus, it is possible that in schizophrenia there is a reduction in GABAergic function which leads to a
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dysregulation of dopamine and the production of psychotic symptoms. A more likely candidate, however, appears to be the glutamatergic system. Glutamatergic dysfunction, particularly at the level of the N-methyl-D-aspartate (NMDA) receptor, has also been implicated in the pathophysiology of schizophrenia. Drugs which are antagonistic at the NMDA receptor, such as ketamine and phencyclidine, produce in healthy volunteers, both the positive, negative and neurocognitive symptoms that are characteristic of schizophrenia21. There is evidence that the propsychotic effects of these drugs may be mediated via an increase in the release of glutamate acting on non-NMDA receptors22. If the function of NMDA receptors themselves is decreased this may remove the glutamatergic
PERCENTAGE CHANGE IN POSITIVE PSYCHOTIC SYMPTOMS
Elevated mood
Depressed mood
No consistant mood change
Percentage change
100 80 60 40 20 0
a vs. b p < 0.05
0
1
a vs. b p < 0.05
a vs. b p < 0.01
2
3
4
0
1
2
3
4
0
1
2
3
4
Time (weeks) Placebo (a) Pimozide (b)
Figure 4.12 Change in positive psychotic symptoms in patients randomized to either the antipsychotic pimozide or to placebo. The groups were subdivided on the basis of the presence of elevated mood, depressed mood or no consistent mood change. The fact that pimozide significantly reduced positive psychotic symptoms in all three groups provided evidence that the ‘neuroleptics’ are in fact antipsychotic rather than ‘antischizophrenic’. Figure reproduced with permission from Johnstone EC, Crow TJ, Frith CD, Owens DG. The Northwick Park “functional” psychosis study: diagnosis and treatment response. Lancet 1988;2:119–25
drive to inhibitory GABAergic neurons which further regulate the excitatory neurons acting on areas such as the frontal cortex and the limbic regions. Thus, with decreased inhibitory control these neurons may increase firing in these areas and produce psychotic symptoms23. Thus, reducing glutamate release at all glutamate receptors may also have a role in improving symptoms in schizophrenia.
EFFICACY OF ANTIPSYCHOTICS IN THE ACUTE PHASE OF TREATMENT The best known large-scale clinical trial, which gives a good idea of the treatment effect to be expected with antipsychotics, was carried out by the National Institutes of Mental Health, in the USA24. This study involved four treatment groups (chlorpromazine, thioridazine, fluphenazine and
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placebo) with 90 randomly allocated subjects in each. The subjects were treated for 6 weeks and rated on 14 different symptoms in addition to global clinical improvement. In this study 75% of subjects in the chlorpromazine, thioridazine and fluphenazine groups showed significant improvement, 5% failed to be helped and 2% deteriorated. In the placebo group only 25% of patients showed significant improvement, and over 50% were unchanged or worse. Johnstone and co-workers25, showed that pimozide was antipsychotic (i.e. reducing the positive symptoms of psychosis) in patients with ‘functional’ psychosis, regardless of whether the patients had prominent manic or depressive symptoms or were euthymic. This proved that ‘neuroleptics’, as they were then popularly called, were truly antipsychotic rather than simply antischizophrenic (Figure 4.12).
Figure 4.13 The upper line represents the percentage of patients with schizophrenia who remained stable after gradual reduction of antipsychotic medication. The lower line represents patients whose medication was abruptly stopped. These results indicate that abrupt cessation of antipsychotic medication produces a much higher risk of relapse in schizophrenia than a gradual reduction. Figure reproduced with permission from Viguera AC, Baldessarini RJ, Hegarty JD, et al. Clinical risk following abrupt and gradual withdrawal of maintenance neuroleptic treatment. Arch Gen Psychiatry 1997;54: 49–55
RELAPSE AFTER STOPPING ANTIPSYCHOTICS
Percentage remaining stable (%)
100 Gradual (n = 58) Abrupt (n = 49)
90 80 70 60 50 40 30 20 0
4
8
12
16
20
24
Weeks after stopping antipsychotic therapy
Davis and Andriukaitis26 performed a metaanalysis using the trials involving chlorpromazine, to investigate the relationship between dose and clinical effect. They noted that a threshold of 400 mg chlorpromazine was required. This was based on the fact that in 31 trials using a dose of 400 mg chlorpromazine/day, only one trial failed to show that chlorpromazine was more effective than the non-antipsychotic reference treatment, whereas in the 31 trials using a dose < 400 mg of chlorpromazine, 19 had failed to show a significant effect. No comparative trials have shown a consistent superiority in any treatment outcome for one conventional or typical antipsychotic over another in the acute treatment of schizophrenia27.
PHARMACOTHERAPY AS MAINTENANCE TREATMENT IN SCHIZOPHRENIA Although it is widely accepted that antipsychotic medication is the mainstay of treatment in acute schizophrenia, its role in long-term maintenance has been more contentious. Nevertheless, the
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importance of maintenance drug therapy in the treatment of chronic schizophrenia has been evident since the early 1960s. Initial studies indicated that between one-half and two-thirds of patients with schizophrenia who were stable on medication relapsed following cessation of maintenance pharmacological therapy, compared with between 5 and 30% of the patients maintained on medication28–30. In a review of 66 studies from 1958 to 1993, Gilbert and colleagues31 noted that relapse rate in the medication withdrawal groups was 53.2% (follow-up 6.3–9.7 months) compared with 15.6% (follow-up 7.9 months) in the maintenance groups. There was also a positive relationship between risk of relapse and length of follow-up. Viguera and colleagues32 investigated the relationship between gradual (last depot injection or tailing off over 3 weeks or more) and abrupt medication discontinuation. They noted a cumulative relapse rate of about 46% at 6 months and 56.2% at 24 months of follow-up in patients whose medication was stopped abruptly. They calculated that in patients whose medication was
Table 4.2 Results of four studies comparing continuous medication treatment with ‘targeted’ or ‘crisis’ medication treatment. In the latter condition the patients only received medication when psychotic symptoms appeared and medication was stopped when these symptoms had resolved. Treatment was 24 months in all studies. As can be seen, although the targeted/crisis groups received lower total doses of medication they were significantly more likely to have a relapse of their psychotic illness than patients receiving continuous medication. Table adapted with permission from reference 33
Study characteristics
Herz et al. (1991)35
Carpenter et al. (1990)36
Jolley et al. (1990)37
Gaebel et al. (1993)38
Number
101
116
54
365
Patient population hospitalized
outpatients
recently discharged
outpatients
recently
Stabilization
3 months
8 weeks
6 months
3 months postdischarge
Psychosocial support
weekly support groups
individual case managers
monthly RN/MD visits
special outpatient clinics
Control features
random/doubleblind
random/non-blind
random/fluphenazinerandom/non-blind decanoate double-blind
Dosage Continued
290*
1.7**
Targeted early
150
1.0
Targeted crisis
–
Continued Targeted early
1616=
208= =
298
91
–
–
118
10
33
9
15
29
55
22
35
Continued
17
39
14
23
Targeted early
36
62
54
49
12-month relapse (%)
24-month relapse (%)
*mg/day
expressed in chlorpromazine (CPZ) eqivalents; **1=low, e.g. <300 mg CPZ; 2=moderate, e.g. 301–600 mg/day; = mean total dose expressed in haloperidol equivalents; = =cumulative dosage over 2 years in 1000 g CPZ equivalents
stopped gradually, the relapse rate at 6 months was halved. Fifty percent of in-patients had relapsed by 5 months after cessation of medication, whilst in their out-patient group relapse rates remained less than 50% to 4 years’ follow-up (Figure 4.13). Thus, findings from medication discontinuation studies have conclusively shown that, as a
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group patients with schizophrenia fare better if they receive antipsychotic medication. However, prolonged use of antipsychotic medication, particularly the older typical antipsychotics, carries a high risk of adverse effects, particularly tardive dyskinesia. In order to minimize the risk of these events, much recent work has focused on the use of low-dose medication regimes.
SIDE-EFFECTS OF CONVENTIONAL ANTIPSYCHOTICS
0
10
20
30
40
50
Figure 4.14 Graphical representation of the point prevalence of extrapyramidal side-effects in 88% of all known schizophrenics living in Nithsdale, Southwest Scotland (n = 146), treated with conventional antipsychotics. There was no relationship between antipsychotic plasma levels and akathisia, parkinsonism or tardive dyskinesia. Figure reproduced with permission from McCreadie RG. Robertson LJ. Wiles DH. The Nithsdale schizophrenia surveys. IX: Akathisia, parkinsonism, tardive dyskinesia and plasma neuroleptic levels. Br J Psychiatry 1992;160:793–9
60
Percentage point prevalance One or more movement disorders Tardive dyskinesia
Parkinsonism Akathisia/pseudoakathisia
Low-dose antipsychotics The rationale underlying the use of low-dose strategies is that significantly lower doses of medication are required for the maintenance, as opposed to the acute treatment, of schizophrenia. This assumes that all major treatment goals have been met for the patients by the time of dose reduction. The two major aims are to ensure that the stability of symptomatic improvement is at least maintained and to minimize the risk of neurological side-effects and secondary negative symptoms caused by higher doses of antipsychotics, particularly typical antipsychotics. A number of trials have investigated the use of standard doses of depot antipsychotics (between 250–500 mg chlorpromazine equivalents) in comparison with continuous ‘low dose’ regimes, usually at least 50% less (reviewed in references 33 and 34). On the whole, these studies have indicated that the patients treated with the lower doses of antipsychotics have a higher rate of exacerbations of their psychotic symptoms and
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higher rates of relapse. Barbui and colleagues34 quoted a relative risk of relapse of 45–65% in the low-dose groups at 12 months’ follow-up; with the relapse rate highest in the group with the lowest dose (50 mg chlorpromazine equivalents/day).
Intermittent or targeted medication This treatment strategy is based on the assumption that patients can be maintained with intermittently administered low doses of antipsychotics. To summarize the results from the main published studies35–38, it appears that patients receiving intermittent targeted therapy while receiving less medication than those on continuous therapy, have a higher rate of relapse and may have a higher rate of re-hospitalization. At 2 years there is little difference in social functioning or psychopathology between the two groups. However, because of the increased risk of relapse and hospitalization, intermittent targeted treatment is no longer generally recommended (Table 4.2).
SIDE-EFFECTS OF TYPICAL ANTIPSYCHOTICS Acute neurological side-effects Acute neurological side-effects secondary to dopamine D2 receptor blockade with typical antipsychotics include acute dystonia. This is characterized by fixed muscle postures with spasm, e.g. clenched jaw muscles, protruding tongue, opisthotonos, torticollis, oculogyric crisis (mouth open, head back, eyes staring upwards). It appears within hours to days and young males are most at risk. It should be treated immediately with anticholinergic drugs (procyclidine 5–10 mg or benztropine 50–100 mg) intramuscularly or intravenously. The response is dramatic.
Medium-term neurological side-effects Medium-term neurological side-effects due to D2 blockade include akathisia and parkinsonism (Figure 4.14)39. Akathisia is an inner and motor, generally lower limb, restlessness. It is usually experienced as very distressing by the patient, and can lead to increased disturbance. Treatment is by reducing the neuroleptic dose and/or propranolol, not with anticholinergics. Akathisia usually appears within hours to days. Parkinsonism is due to blockade of D2 receptors in the basal ganglia. The classical features are a mask-like facies, tremor, rigidity, festinant gait and bradykinesia. It appears after a few days to weeks and treatment involves use of anticholinergic drugs (procyclidine, orphenadrine), reduction in antipsychotic dose, or switching to an ‘atypical’ antipsychotic which is less likely to produce such extrapyramidal symptoms (Figure 4.15).
Chronic neurological side-effects The chronic neurological side-effects due to D2 blockade are tardive dyskinesia and tardive dystonia. Tardive dyskinesia is usually manifested as orofacial dyskinesia and the patient exhibits lip smacking and tongue rotating. Tardive dystonia appears as choreoathetoid movements of the head, neck and trunk. It appears after months to years. There is an increased risk of tardive
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dyskinesia in older patients, females, the edentulous and patients with organic brain damage. With chronic use of antipsychotics, 20% or more of patients will develop tardive dyskinesia. Although there is no clear relationship with duration or total dose of treatment, or class of antipsychotic used there is a cumulatively increased risk with length of exposure (Figure 4.16)40. Increasing the dose may temporarily alleviate symptoms, and reducing the dose may exacerbate them. Clozapine, olanzapine and quetiapine have been shown to improve symptoms, and with risperidone and amisulpride, have a lower propensity to cause tardive dyskinesia.
Neuroendocrine effects The effect of D2 blockade on the neuroendocrine system produces hyperprolactinemia by reducing the negative feedback on the anterior pituitary. High serum levels of prolactin produce galactorrhea, amenorrhea and infertility.
Idiosyncratic effects The most life-threatening side-effect of neuroleptic use is neuroleptic malignant syndrome (NMS). This is thought to be due to derangement of dopaminergic function, but the precise pathophysiology is unknown. Symptoms include hyperthermia, muscle rigidity, autonomic instability and fluctuating consciousness. It is an idiosyncratic reaction. The diagnosis is often missed in the early stages, but a raised level of creatine phosphokinase is often seen. It can occur at any time. The untreated mortality rate is 20% and therefore immediate medical treatment is required. Bromocriptine (a D1/D2 agonist) and dantrolene (a skeletal muscle relaxant) are used to reverse dopamine blockade and for muscular rigidity, respectively. The management includes supportive treatment for dehydration and high temperature. Renal failure from rhabdomyolysis is the major complication and cause of mortality. NMS can recur on reintroduction of antipsychotics; it is therefore recommended to wait at least 2 months and introduce a drug of a different class at the lowest effective dose.
Antidopaminergic side-effects due to D 2 receptor blockade Acute/medium term neurological side-effects Akathisia and Parkinsonism
Acute neurological side-effects Acute dystonia
Idiosyncratic side-effects Neuroleptic malignant syndrome D2
D2 Chronic neurological side-effects Tardive dyskinesia Tardive dystonia
Anticholinergic side-effects due to muscarinic acetyl choline receptor blockade
Blurred vision Dry mouth
Idiosyncratic side-effects due to histaminergic (H1) and adrenergic ( Ȋ1) receptor blockade
Photosensitivity Retinal pigmentation
Hypotension Arrhythmia
Constipation Urinary retention
Neuroendocrine effects Amenorrhea Galactorrhea Infertility
α1
Cholestatic jaundice Heat sensitivity
Ejaculatory failure H1
Sedation
Figure 4.15 Side-effects with antipsychotics. Side-effects will vary between drugs depending on their receptor profile. In general as all antipsychotics produce some degree of dopamine D2 receptor blockade they are all likely to produce neurological side-effects above a certain dose, with the exception of clozapine and quetiapine
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Figure 4.16 With prolonged exposure to conventional antipsychotics there is a cumulative risk of tardive dyskinesia with time. Figure reproduced with permission from Glazer WM, Morgenstern H, Doucette JT. Predicting the long-term risk of tardive dyskinesia in out-patients maintained on neuroleptic medications. J Clin Psychiatry 1993;54:133–9
RISK OF TARDIVE DYSKINESIA
Percentage of patients with tardive dyskinesia
30
20
10
0 0
1
2
3
4
5
6
Years on medication
Anticholinergic side-effects include a dry mouth (hypersalivation with clozapine), difficulty urinating or retention, constipation, blurred vision and ejaculatory failure. Profound muscarinic blockade may produce a toxic confusional state. The sedative effects of antipsychotics are primarily produced by the blockade of histamine-1 receptors. Side-effects due to a-adrenergic blockade include postural hypotension, cardiac arrhythmias and impotence. Some side-effects may be due to autoimmune reactions such as urticaria, dermatitis and rashes. Dermal photosensitivity and a gray/blue/purple skin tinge are more commonly seen with the phenothiazines, as are the conjunctival, corneolenticular and retinal pigmentation sometimes reported. Cholestatic jaundice due to a hypersensitivity reaction is now rarely seen with chlorpromazine and was possibly due to an impurity. Weight gain is also frequently seen with a wide variety of antipsychotics. This may be due to increased appetite, and although the mechanism is unclear, it may be due to a combination of histamine-1 and 5-HT2C receptor blockade.
Cardiac conduction effects of antipsychotics Recently, concern has grown over the ability of antipsychotic medications to produce changes in
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cardiac conduction. QTC interval prolongation is the most widely reported conduction deficit. This first came to attention after sudden deaths secondary to arrhythmias with pimozide. The UK Committee for the Safety of Medicines’ (CSM) advice about pimozide is that all patients should have an electrocardiogram (ECG) prior to starting treatment and patients with a known arrhythmia or prolonged QT interval should not receive the drug. Sertindole, an atypical antipsychotic, was voluntarily suspended from sale by its manufacturers in 1997 after similar concerns. Most recently the CSM has advised on restrictions to the use of thioridazine and droperidol as these medications produce the most profound QTC prolongations41. The QT interval on the standard ECG represents the interval between the end of ventricular depolarization and the end of cardiac repolarization. The ‘c’ in QTC indicates that the QT value quoted has been corrected for cardiac rate. It is thought that prolongation of this interval increases the risk of a potentially fatal ventricular arrhythmia known as torsade-de-pointes. The mechanism of this is becoming clearer and implicates the blockade of the delayed rectifier potassium channel (I(kr)). Blockade of this receptor in the heart prolongs cardiac repolarizaton and thus the QTC interval. It is known that drugs most
Table 4.3 Amisulpride vs. reference antipsychotics – selectivity for recombinant human D2/D3 receptor subtypes. Amisulpride only has appreciable affinity for D2 and D3 receptors in contrast to the other antipsychotics in this table. It has relatively high affinity for both receptors. The implications of this for amisulpride’s mechanism of action and atypicality are hypothesized to involve an increased tendency to bind to presynaptic D2 and D2-like receptors. Table reproduced with permission from Schoemaker H, Claustre Y. Fage D, et al. Neurochemical characteristics of amisulpride, an atypical dopamine D2/D3 receptor antagonist with both presynaptic and limbic selectivity. J Pharmacol Exp Ther 1997;280:83–97
Positively coupled with adenyl cyclase
Negatively coupled with adenyl cyclase
Compound
D1
D5
Amisulpride
>10000
>10000
2.8
3.2
Haloperidol
27
48
0.6
3.8
Clozapine
141
250
80
230
89
Olanzapine
250
–
17
44
–
Risperidone
620
–
13
–
specifically associated with QTC interval prolongation bind specifically to the I(kr)42. Although there is little consensus as to what represents a ‘normal’ QTC it is generally accepted that a QTC of over 500 ms increases the likelihood of an arrhythmia. When interpreting data on medication-related QTC prlongation it is important to note that the mean daily QTC intrasubject variability is 76ms43. Other risks factors which increase the likelihood of QTC prolongation include age over 65 years and co-administration of other drugs associated with cardiac arrythmias, such as tricyclic antidepressants. Safety studies are ongoing with both the newer and the older medications, preliminary data suggests that the newer medications do not differ significantly in their likelihood to prolong the QTC interval.
THE NEWER ‘ATYPICAL’ ANTIPSYCHOTICS The reintroduction of clozapine in the early 1990s and the subsequent release of several new, ‘atypical’ antipsychotics has increased optimism in the treatment of schizophrenia. As these are likely to be the mainstay of treatment for schizophrenia in the future, it is worthwhile considering them individually (Figure 4.17 and Table 4.3)44,45.
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D2
3.3
D3
D4 >1000 3.8
Clozapine Clozapine, the prototypical third-generation antipsychotic, has been used since the 1960s for treatment of schizophrenia. However, after reports of several deaths from neutropenia, in most countries clozapine can be used only in patients unresponsive to two other antipsychotics given at an adequate dose for an adequate duration, or those with tardive dyskinesia or severe extrapyramidal symptoms, and only with blood monitoring. Each patient has to be registered and the drug is dispensed only after a normal white cell count. In the UK, a blood count is performed every week for 18 weeks, then every 2 weeks for the next year, and thereafter monthly. In the USA, blood monitoring is weekly throughout treatment. Clozapine is contraindicated for those with previous neutropenia. Important aspects of clozapine’s pharmacology include its low affinity for the D2 receptor, in comparison with older antipsychotics. Clozapine has higher affinity at the D1 and D4 receptors than at the D2 receptor and also binds to the extrastriatal D2-like receptor, the D3 receptor. It is thought that the low incidence of extrapyramidal side-effects is due to the low activity at the D2 receptor. Clozapine also has antagonistic activity at the 5HT1A, 5HT2A , 5HT2C and 5HT3
Figure 4.17 A representation of the absolute receptor affinity of haloperidol in comparison with some of the newer ‘atypical’ antipsychotics drawn from data in reference 112. Each line represents a single receptor, the further along the bar on a given line the higher the affinity of that medication for that receptor. Each of the gradations on the lines represents 10 times greater affinity for that receptor. What can be seen from this is that clozapine, quetiapine and to a lesser extent olanzapine have much lower affinities for the dopamine D2 receptor than haloperidol. This may be why they are ‘atypical’ in terms of producing fewer extrapyrimidal side-effects than antipsychotics such as haloperidol. Risperidone and ziprasidone have similar D2 receptor affinities to haloperidol and yet they too are ‘atypical’. It has been hypothesized that very high affinity for the serotonin-2A receptor, (5-HT2A), may underlie the atypicality of ziprasidone and risperidone. Indeed this may be important for ‘atypicality’ per se, as all of the newer medications have a higher affinity for the 5-HT2A than for the D2 receptor. Amisulpride, by contrast to the medications in this figure, only has appreciable affinity for D2 and D3 receptors and has high equipotent affinity for both receptors, as can be seen in Table 4.3. Data from reference 45
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Figure 4.18 Comparison of efficacy of clozapine versus chlorpromazine in treatment-resistant schizophrenia. Figure reproduced with permission from Kane J, Honigfeld G, Singer J, Meltzer H. Clozapine for the treatment-resistant schizophrenic: a double blind comparison with chlorpromazine. Arch Gen Psychiatry 1988; 45:789–96
CLOZAPINE vs. CHLORPROMAZINE IN TREATMENT-RESISTANT SCHIZOPHRENIA
Proportion of Patients Responding
30% 25% 20% 15% 10% 5% 0%
Clozapine
Chlorpromazine
receptors. It is postulated that it is the balance between the blockade of these receptors that underlies clozapine’s clinical efficacy in improving positive and negative symptomatology. Clozapine is an antagonist at the α1 receptor but less so at the α2 receptor, resulting in sedation and hypotension. Clozapine’s antagonism at the histamine H1 receptor adds to the sedative effects and may be, in part, responsible for weight gain. Other sideeffects include hypersalivation, tachycardia, sedation and hypotension. More rarely, clozapine can produce seizures (approximately 1%) and blood dyscrasias (< 1–2%). The risk of neutropenia is 1–2%, and in most cases is reversible. The majority of cases (83%) occur within the first 20 weeks of treatment. Risk of agranulocytosis decreases to 0.07% after the first year of treatment. Agranulocytosis probably results from toxic and immunological factors (reviewed in reference 46). It is this last potentially fatal side-effect that has led to the limits on the use of clozapine and the requirement for blood monitoring in patients receiving clozapine. Interestingly, clozapine does not increase serum prolactin. Clozapine is the most effective treatment for schizophrenic patients refractory to other therapies,
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and improves both positive and negative symptoms. In non-comparative studies, clozapine has led to > 15% improvement in baseline ratings in 30–70% of previously treatment-refractory patients after 2–6 months of treatment (reviewed in reference 46). In comparison to chlorpromazine47–49 (Figure 4.18), haloperidol50 or fluphenazine51, clozapine shows a 30–100% response rate, versus a 4–17% rate for the comparator, when administered to patients resistant to previous treatment with classical antipsychotics. Clozapine has been investigated in few randomized controlled trials of maintenance therapy. This is due to the restrictions imposed on its use. In one of the few studies published, Essock and co-workers52 followed up a sample of 227 patients randomized to either clozapine or treatment as usual. They reported that those treated with clozapine had significantly greater reductions in side-effects, disruptiveness, hospitalization and readmission after discharge. Furthermore, the clinical efficacy of clozapine in relapse prevention is well established, naturalistically, at 1–2 years of treatment and there have been reports of good maintenance efficacy for up to 17 years of treatment (for review see reference 46).
Risperidone This drug has high affinity for the 5-HT2A receptor, with a similar affinity at the D2 receptor to most typical antipsychotics. In the acute phase of treatment, risperidone appears as effective as haloperidol in terms of improvement in positive and secondary negative symptom scores53. The optimal dose of risperidone appears to be between 4 and 6 mg/day. At doses higher than 8–12mg/day risperidone can cause extrapyramidal side-effects of tremor, rigidity and restlessness, with a similar frequency to typical antipsychotics. Risperidone can increase serum prolactin which may lead to sexual dysfunction. Risperidone has been assessed for long-term efficacy and safety in a number of long-term openlabel studies. Earlier data suggested that long-term therapy with risperidone was associated with a meaningful reduction in psychopathology, amelioration of extrapyrimidal side-effects (EPS) and improved social functioning from baseline measures or against placebo. More recently a meta-analysis of eleven of the risperidone/conventional antipsychotic comparator randomized controlled trials was performed54. The author reported that slightly but significantly more patients on risperidone showed clinical improvement than with comparison antipsychotics (57% vs. 52%) and used significantly less medication for EPS (29.1% vs. 33.9%).
Olanzapine A more broad-spectrum atypical antipsychotic, olanzapine has a side-effect profile similar to that of clozapine but with a higher incidence of extrapyrimidal side-effects at doses above 20 mg/day. Olanzapine also demonstrates antagonistic effects at a wide range of receptors, but has a higher affinity for D2 and 5-HT2A receptors than clozapine and a lower affinity at the D1 receptor subtype. In acute-phase studies, olanzapine is efficacious for positive and secondary negative symptoms and was superior to haloperidol on overall
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improvement according to the Brief Psychiatric Rating Scale (BPRS)55 and every other secondary measure. Standard-dose olanzapine (5–15 mg/day) has been shown to be an effective maintenance treatment for schizophrenia in comparison with placebo56. The estimated 1-year risk of relapse with olanzapine was 19.6–28.6% for standarddose olanzapine in comparison with a 69.9% risk of relapse with placebo. Initial data from a metaanalysis of three studies using haloperidol-treated patients as a test group, indicated that 80.3% of patients receiving olanzapine maintained their response at 1 year in comparison with 72% for haloperidol-treated patients57.
Quetiapine Another broader-spectrum atypical, quetiapine has a similar receptor binding profile to clozapine, but with relatively lower affinity for all receptors and virtually no affinity for muscarinic receptors. Quetiapine is effective in acute phase studies for the treatment of positive and secondary negative symptoms. Initial randomized controlled trials indicated that quetiapine (250–750mg, n=96) was more effective than placebo (n = 96) and that this efficacy was not seen at doses of less than 250 mg/day of quetiapine58. In comparison with chlorpromazine, response rates to quetiapine were similar across all symptom domains59. Response rates between haloperidol- and quetiapine-treated groups are also similar60. In all of these studies, the rates of EPS with quetiapine were similar to those seen in placebotreated groups and significantly lower than in conventional antipsychotic comparator groups. Most common side-effects are somnolence and dry mouth. Quetiapine demonstrates a lower potential to cause weight gain than clozapine and olanzapine, and does not increase serum prolactin61. In long-term studies, quetiapine was well tolerated with up to 75% of respondents to a questionnaire denying any side-effects from quetiapine62.
Amisulpride In contrast to all the other newer antipsychotics, amisulpride only has effects on the dopamine D2 and D3 receptors, where it is a potent antagonist. In animal models at lower doses, amisulpride appears to bind preferentially to presynaptic D2 receptors64, and at projected therapeutic levels it also appears to be selective, in a neurochemical imaging study in humans, for limbic D2 and D3 receptors63. It has a similar efficacy to haloperidol for positive symptoms in acute exacerbations of schizophrenia64–67, with a projected optimum dose in this group of between 400 and 800 mg/day66. Some studies at this dose range have reported a significantly greater efficacy for amisulpride in comparison with placebo for treating the negative symptoms of schizophrenia65,66. In all of the studies above, amisulpride has a significantly lower incidence of extrapyrimidal side-effects, at doses below 1200 mg/day, than haloperidol. Amisulpride may cause less weight gain than other atypical antipsychotics but it does increase plasma prolactin68,69. In a 12-month trial of amisulpride 200–800 mg/day versus haloperidol 5–20 mg/day, amisulpride showed enhanced efficacy for positive and negative symptoms in comparison with haloperidol. Those treated with amisulpride had significantly greater improvement in quality of life and significantly fewer extrapyrimidal side-effects. Long-term efficacy and relapse prevention were similar in the amisulpride- and haloperidol-treated groups70.
Ziprasidone Ziprasidone has a high 5HT2A/D2 receptor blockade ratio and a similarly high affinity for the 5HT2A receptor to risperidone and sertindole. It is an agonist at the 5HT1A receptor. Ziprasidone also has potent affinity for D3 and moderate affinity for D4 receptors. It exhibits weak serotonin and noradrenergic reuptake inhibition. Ziprasidone appears to have relatively low levels of side-effects. These may include somnolence and headache, but results of full clinical studies remain to be published.
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An initial clinical trial of ziprasidone versus haloperidol 15 mg/day over 4 weeks suggested that ziprasidone 160 mg/day was as effective as haloperidol at reducing positive symptom scores, but produced fewer side-effects71. In two placebocontrolled trials lasting 4 and 6 weeks, respectively72,73, the pooled data indicated that ziprasidone 80–160 mg was consistently significantly more effective than placebo and lower doses of ziprasidone. Improvements in positive and negative symptoms were similar in magnitude to those seen in patients treated with risperidone, olanzapine or quetiapine. Interestingly, 160 mg of ziprasidone was associated with a greater than 30% decrease in depressive symptoms in the subgroup of patients with significant depression at the outset of the trials. Ziprasidone has also been used in a 1-year placebo-controlled trial in order to assess its utility for relapse prevention. A total of 294 patients were studied and randomized to placebo treatment or ziprasidone 40–160 mg/day. At 6 months into the study, 117 patients remained on ziprasidone and 23 on placebo. Of these, only 6% of the ziprasidone-treated patients had experienced an exacerbation of their symptoms over the subsequent 6 months, in comparison with 35% in the placebo-treated group74.
NEW ANTIPSYCHOTICS CURRENTLY IN PHASE III CLINICAL TRIALS Iloperidone Iloperidone is a benzisoxazole derivative and is therefore from the same chemical class as risperidone. As for risperidone, iloperidone has a high affinity for the 5-HT2A receptor and a lower affinity for the D2 receptor, although in absolute terms its affinity for the D2 receptor is of a similar order of magnitude to haloperidol and risperidone. Relative to other newer antipsychotics iloperidone has a higher affinity for 5-HT1A receptors and lower affinity for 5-HT2C receptors75. It also has high affinity for a1 receptors but no affinity for acetylcholine muscarinic M1 receptors.
In early phase II placebo controlled trials, iloperidone at 8 mg per day was superior to placebo in improving positive and negative symptoms with EPS at placebo levels. The most frequently described side-effects were dizziness, postural hypotension and nausea76. A large scale multicenter trial comparing iloperidone 4mg, 8mg and 12mg with haloperidol 15 mg per day and placebo in a total of 621 patients over 42 days has recently been completed77. Initial data indicates clinical response similar to haloperidol but with significantly lower rates of EPS (similar to placebo).
Aripiprazole Aripiprazole is a quinolinone derivative and differs from other novel antipsychotics in that rather than being an antagonist at dopamine receptors, it appears to be a high affinity partial agonist at presynaptic D2 receptors but exhibits antagonist effects on postsynaptic D2 receptors78. It has low affinity for D3 and D4 receptors and no appreciable affinity for D1-like receptors. Its affinity for 5-HT2A receptors is low and of a similar magnitude to that of clozapine. In phase II clinical studies, aripiprazole is significantly superior to placebo at improving the total score of the PANSS79. A recently completed phase III clinical trial compared aripiprazole 15mg or 30 mg per day with haloperidol 10 mg per day and placebo in a total of 414 patients for 28 days. The preliminary results from this study show that both doses of aripiprazole are significantly better than placebo at improving PANSS total score and equivalent to haloperidol. Aripiprazole at both doses lead to placebo rates of EPS which is significantly lower than the rate seen in the patients treated with haloperidol80.
ADVERSE EVENTS OF ATYPICAL ANTIPSYCHOTICS The issue of side-effects or adverse events is closely linked to tolerability and acceptability and therefore to both compliance and relapse prevention. Often the most debilitating and obvious sideeffects of conventional antipsychotics are motor.
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As described above, all of the newer antipsychotics demonstrate a lower propensity to cause EPS at clinically effective doses. There is increasing evidence that these drugs may additionally provide benefits for patients who suffer from akathisia and tardive dyskinesia. Indeed, it is in the area of tardive dyskinesias that clozapine appears to have its most marked effect. Lieberman and associates81 reported a 50% reduction of symptoms over 28 months of treatment in 43% of patients, and Gerlach and Peacock82 reported a resolution of tardive dyskinesia in 54% of patients after 5 years of clozapine treatment. Furthermore, Tamminga and colleagues83 reported a significant difference in reduction of tardive dyskinesia scores in a clozapine group versus a haloperidol-treated group and that this difference began after about 4 months of treatment. There have also been case reports that switching to clozapine has been effective in reducing tardive dystonia84. Initial data from the studies quoted above on the newer antipsychotics indicates that they too produce very low rates of tardive dyskinesia. The rate of other side-effects may vary between each of the newer drugs, although fully adequate comparison studies remain to be published (Table 4.4)85.
Negative symptoms It is claimed that clozapine has an almost unique action against the negative symptoms of schizophrenia, out of proportion to its effect on positive symptoms86, but the evidence for this is by no means clear. Tandon and associates87 found that the improvement in negative symptoms covaried with the improvement in positive symptoms, and Hagger and co-workers88 found no improvement in negative symptoms. A more recent finding is that in comparison with haloperidol, clozapine had a significant effect on negative symptoms in patients with non-deficit schizophrenia, but not in those with deficit schizophrenia, i.e. those with enduring negative symptoms89,90. It has therefore been suggested that clozapine’s apparently beneficial effect on negative symptoms may simply be a reflection of its reduced tendency to cause EPS91. The weight of current evidence suggests that
Table 4.4 Qualitative comparison of the relative side-effects of the newer medications. These will be subject to change over time, as new tolerability data are published and report forms returned. Adapted from reference 85
Typicals
Clozapine
Risperidone
Olanzapine
Quetiapine
Amisulpride
Ziprasidone
Anticholinergic
±
+++
±
+
±
±
±
Orthostatic hypotension
± to +++
+++
+
±
+
±
±
Prolactin elevation
++ to +++
0
++
±
±
++
±
± to +
+
± to +
± to +
± to +
±
± to +
Sedation
+ to +++
+++
+
++
++
±
+
Seizures
±
++ to +++
±
±
±
±
±
± to ++
+++
+ to ++
+++
+ to ++
± to +
±
QT prolongation
Weight gain
clozapine has an excellent effect on the secondary, but not primary, negative symptoms92. All of the newer antipsychotics appear to have an effect on secondary negative symptoms. Most of the available trials have indicated a modest but significant advantage for all of the newer medications over conventional antipsychotics in negative symptom improvement54,58,87,93. Amisulpride at low doses (50–300 mg/day) is claimed to have a unique effect in patients with only negative symptoms. In comparison with placebo, these low doses of amisulpride produced significant reductions in negative symptom scores with little change in positive symptom scores94–96. However, in a study utilizing a different design but similar patient population, low-dose amisulpride was similar to low-dose haloperidol treatment in terms of negative symptom improvement97.
Cognition Neurocognitive deficits that are a core feature of schizophrenia, are apparent at the onset of illness and may deteriorate during the first few years of illness. The older antipsychotics have limited
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impact on these, although inconsistent long-term improvements have been noted98,99. There has been increasing interest in the possibility that the newer antipsychotics may ameliorate these problems which are linked to poor outcome and future unemployment. Clozapine may lead to improvements in attention, memory and executive function over 6–12 months100. Risperidone is claimed to improve frontal function and spatial working memory compared with haloperidol101,102. Olanzapine is claimed to improve a variety of measures of function including psychomotor speed, verbal fluency and memory103. It has recently been reported that quetiapine improves attentional performance to the level of that seen in a matched control group over 2 months of treatment104. In a study comparing haloperidol 1 mg and 2 mg and amisulpride 50 mg and 100 mg with placebo in healthy volunteers, the haloperidol-treated groups showed greater cognitive impairment on tasks measuring problemsolving abilites105. It is still not clear how relevant the modest improvements or impairments reported in these studies are to long-term outcome.
COMPARISON OF ATYPICAL AND TYPICAL ANTIPSYCHOTICS
−< 12 mg
< 12 mg −<
haloperidol
haloperidol
>12 mg
>12 mg
haloperidol
haloperidol
–0.5
–0.4
–0.3
–0.2
–0.1
Favors atypical
0
0.1
-0.5
-0.4
-0.3
-0.2
-0.1
Favors atypical
Favors haloperidol
0
0.1
Favors haloperidol
Figure 4.19 Results from a meta-analysis of trials comparing newer atypical antipsychotics and typical antipsychotics (mainly haloperidol). The left graph suggests that the clinical superiority of atypical antipsychotics over typical antipsychotics is lost if lower doses of typical antipsychotics are used (less than 12 mg per day of haloperidol equivalents). The right-hand graph, suggests that any superiority in tolerability for the atypical antipsychotics is similarly lost if patients receive lower doses of typical antipsychotics. These findings and interpretations have been criticized on a number of counts including selection bias in the trials chosen for the meta-analysis, no similar control for the doses of atypicals used and using the drop-out rates from clinical trials as a measure of medication tolerability. Figure reproduced with permission from Geddes J, Freemantle N, Harrison P, Bebbington P. Atypical antipsychotics in the treatment of schizophrenia: systematic overview and meta-regression analysis. Br Med J 2000;321:1371–6
Affective symptoms Patients with schizophrenia are significantly more likely than the general population to suffer from other psychiatric disorders such as depression, and conventional antipsychotics are used to treat other psychotic disorders outside of schizophrenia Clozapine has been reported to be effective in patients with treatment-resistant schizoaffective or manic illnesses106 (see reference 107 for review). In one study, clozapine reduced baseline mania ratings by more than 50% in 72% of a group of patients suffering from either mania or schizoaffective disorder and 32% had a significant improvement in BPRS scores. The latter finding was more frequent in the patients with bipolar disorder and the non-rapid cycling patients108. In depressive disorders, clozapine had a more equivocal response. Although it was seemingly effective against depressive symptoms occurring comorbidly with schizophrenia109, there has been little work showing a particular use for clozapine in treatment-refractory depression110,111.
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Conventional antipsychotics may both improve and contribute towards depressive symptoms. Clozapine reduces both depressive features and suicidality109. Risperidone produces significantly greater reduction in anxiety/depression subscales in comparison with haloperidol52. Olanzapine has significant antidepressant effects in comparison with haloperidol112. Amisulpride (50 mg/day) has been compared with imipramine (100 mg/day) and placebo in patients with dysthymia and major depressive disorder. In this study (n = 219), both imipramine and amisulpride produced similar and significant improvements on all rating scales113. The implications of this in patients with schizophrenia have yet to be elucidated.
THE FUTURE Despite the advances in schizophrenia pharmacotherapy since the early 1950s there are still many limitations. EPS make use of high doses of the older typical antipsychotics problematic and often
unpleasant for those taking them. Lower doses of ‘typicals’ and the newer ‘atypical’ antipsychotics offer benefits in terms of reductions in EPS, but the latter medications are not without their own unpleasant side-effects. In a recent meta-analysis, Geddes and colleagues114 described that in their analysis of all of the trials of atypical antipsychotics versus typical antipsychotics there was no treatment advantage for the newer medications over doses of haloperidol below 12 mg/day and no significant difference in total side-effect load (Figure 4.19). Such meta-analyses have, however, come under criticism for obscuring real treatment effects by being overinclusive of available trials115,116. Furthermore, a recent critical review of treatment trials with low-dose typical antipsychotics could find no convincing evidence that there is a low dose of typical antipsychotics which is effective but does not produce EPS117. Another failing in the pharmacotherapy of schizophrenia is that there are still 40–50% of patients with schizophrenia who do not have an optimal response to medication, and some 20% who are resistant to all forms of treatment, including clozapine. Future developments may include a new generation of antipsychotic drugs which are partial agonists (rather than antagonists) at D2 and D2-like receptors, such as aripiprazole78. As described above, early clinical trials with this medication show good efficacy with placebo rates of EPS80. In conjunction with developments in trial methodology, combinations of neurochemical and functional imaging may help to elucidate the neural correlates of treatment response and resistance and allow more rationale therapeutic decisions. Pharmacogenetics may further help to define the parameters which predict response or nonresponse to particular medications by analyzing the allelic variations for individual receptors which correlate with response118.
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Schoemaker H, Claustre Y, Fage D, et al. Neurochemical characteristics of amisulpride, an atypical dopamine D2/D3 receptor antagonist with both presynaptic and limbic selectivity. J Pharmacol Exp Ther 1997;280:83–97 Schotte A, Janssen PF, Gommeren W. et al. Risperidone compared with new and reference antipsychotic drugs: in vitro and in vivo receptor binding. Psychopharmacology 1996;124:57–73 Travis MJ. Clozapine. A review. J Serotonin Res 1997;4:125–44 Kane J, Honigfeld G, Singer J, Meltzer H. Clozapine for the treatment-resistant schizophrenic: a double blind comparison with chlorpromazine. Arch Gen Psychiatry 1988;45:789–96 Claghorn J, Honigfeld G, Abuzzahab FS Sr, et al. The risks and benefits of clozapine versus chlorpromazine. J Clin Psychopharmacol 1987;7:377–84 Conley RR, Schulz SC, Baker RW, et al. Clozapine efficacy in schizophrenic nonresponders. Psychopharmacol Bull 1988;24:269–74 Breier A, Buchanan RW, Waltrip RWI, et al. The effects of clozapine on plasmanorepinephrine: relationship to clinical efficacy. Neuropsychopharmacology 1994;10:1–7 Pickar D, Owen RR, Litman RE, et al. Clinical and biologic response to clozapine in patients with schizophrenia. Crossover comparison with fluphenazine [see comments]. Arch Gen Psychiatry 1992;49: 345–53 Essock SM, Hargreaves WA, Covell NH, Goethe J. Clozapine’s effectiveness for patients in state hospitals: results from a randomized trial. Psychopharmacol Bull 1996;32:683–97 Marder SR, Davis JM, Chouinard G. The effects of risperidone on the five dimensions of schizophrenia derived by factor analysis: combined results of the North American trials. J Clin Psychiatry 1997;58: 538–46 Song F. Risperidone in the treatment of schizophrenia: a meta-analysis of randomized controlled trials. J Psychopharmacol 1997;11:65–71 Overall JE, Gorham DR. The Brief Psychiatric Rating Scale. Psychological Reports 1962;10:799–812 Tollefson GD, Sanger TM. Negative symptoms: a path analytic approach to a double-blind, placeboand haloperidol-controlled clinical trial with olanzapine. Am J Psychiatry 1997;154:466–74 Dellva MA, Tran P, Tollefson GD, et al. Standard olanzapine versus placebo and ineffective-dose olanzapine in the maintenance treatment of schizophrenia [see comments]. Psychiatric Serv 1997;48: 1571–7 Small JG, Hirsch SR, Arvanitis LA, et al. Quetiapine in patients with schizophrenia. A high- and low-dose
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double-blind comparison with placebo. Seroquel Study Group. Arch Gen Psychiatry 1997;54:549–57 Peuskens J, Link CG. A comparison of quetiapine and chlorpromazine in the treatment of schizophrenia. Acta Psychiatr Scand 1997;96:265–73 Arvanitis LA, Miller BG. Multiple fixed doses of ‘Seroquel’ (quetiapine) in patients with acute exacerbation of schizophrenia: a comparison with haloperidol and placebo. The Seroquel Trial 13 Study Group. Biol Psychiatry 1997;42:233–46 Rak IW, Jone AM, Raniwalla J, et al. Weight changes in patients treated with seroquel (quetiapine). Schizophrenia Res 2000;41(special issue):206 Hellewell JSE, Kalali AH, Langham SJ, McKellar J, Awad AG. Patient satisfaction and acceptability of long-term treatment with quetiapine. Int J Psychiatry Clin Pract 1999;3:105–13 Xiberas X, Martinot JL, Mallet L, et al. In vivo extrastriatal and striatal D2 dopamine receptor blockade by amisulpride in schizophrenia. J Clin Psychopharmacol 2001;21:207 Delcker A, Schoon ML, Oczkowski B, Gaertner HJ. Amisulpride versus haloperidol in treatment of schizophrenic patients – results of a double-blind study. Pharmacopsychiatry 1990;23:125–30 Moller HJ, Boyer P, Fleurot O, Rein W. Improvement of acute exacerbations of schizophrenia with amisulpride: a comparison with haloperidol. PROD-ASLP Study Group. Psychopharmacology 1997;132: 396–401 Puech A, Fleurot O, Rein W. Amisulpride, and atypical antipsychotic, in the treatment of acute episodes of schizophrenia: a dose-ranging study vs. haloperidol. The Amisulpride Study Group. Acta Psychiatr Scand 1998;98:65–72 Carriere P, Bonhomme D, Lemperiere T. Amisulpride has a superior benefit/risk profile to haloperidol in schizophrenia: results of a multicentre, double-blind study (the Amisulpride Study Group). Eur Psychiatry 2000;15:321–9 Coulouvrat C, Dondey-Nouvel L. Safety of amisulpride (Solian): a review of 11 clinical studies. Int Clin Psychopharmacol 1999;14:209–18 Rein W, Coulouvrat C, Dondey-Nouvel L. Safety profile of amisulpride in short- and long-term use. Acta Psychiatr Scand 2000;400(Suppl.):23–7 Colonna L, Saleem P, Dondey-Nouvel L, Rein W. Long-term safety and efficacy of amisulpride in subchronic or chronic schizophrenia. Amisulpride Study Group. Int Clin Psychopharmacol 2000;15:13–22 Goff DC, Posever T, Herz L, et al. An exploratory haloperidol-controlled dose-finding study of ziprasidone in hospitalized patients with schizophrenia or schizoaffective disorder. J Clin Psychopharmacol 1998;18:296–304
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Keck P, Jr, Buffenstein A, Ferguson J, et al. Ziprasidone 40 and 120 mg/day in the acute exacerbation of schizophrenia and schizoaffective disorder: a 4week placebo-controlled trial. Psychopharmacology 1998;140:173–84 Daniel DG, Zimbroff DL, Potkin SG, et al. Ziprasidone 80 mg/day and 160 mg/day in the acute exacerbation of schizophrenia and schizoaffective disorder: a 6-week placebo-controlled trial. Ziprasidone Study Group. Neuropsychopharmacology 1999; 20:491–505 Arato M, O’Connor R, Meltzer H, et al. The ziprasidone extended use in schizophrenia (ZEUS) study: a propective, double blind, placebo controlled, 1 year clinical trial. Data on file, Pfizer Pharmaceutical Group, 1999 Corbett R, Griffiths L, Shipley JE, et al. Iloperidone: Preclinical profile and early clinical evaluation. CNS Drug Reviews 1997;3:120–47 Jain KK. An assessment of iloperidone for the treatment of schizophrenia. Exp Opin Invest Drugs 2000;9:2935–43 Cucchiaro J, Nann-Vernotica E, Lasser R, et al. A randomised double-blind, multicenter phase II study of iloperidone versus haloperidole and placebo in patients with schizophrenia or schizoaffective disorder. Schizophr Res 2001;49:223 Lawler CP, Prioleau C, Lewis MM, et al. Interactions of the novel antipsychotic aripiprazole (OPC14597) with dopamine and serotonin receptor subtypes. Neuropsychopharmacology 1999;20:612–27 Petrie JL, Saha AR, Ali MW. Safety and efficacy profile of aripiprazole, a novel antipsychotic. Presented at the 37th Annual ACNP Meeting Carson WH, Ali M, Saha A, et al. A double-blind placebo controlled trial of aripiprazole and haloperidol. Schizophrenia Res 2001;49(Suppl. 1–2):221–2 Lieberman JA, Saltz BL, Johns CA, et al. The effects of clozapine on tardive dyskinesia. Br J Psychiatry 1991;158:503–10 Gerlach J, Peacock L. Motor and mental side effects of clozapine. J Clin Psychiatry 1994;55(Suppl. B): 107–9 Tamminga CA, Thaker GK, Moran M, et al. Clozapine in tardive dyskinesia: observations for human and animal model studies. J Clin Psychiatry 1994;55(Suppl B):102–6 Shapleske J, Mickay AP, Mckenna PJ. Successful treatment of tardive dystonia with clozapine and clonazepam. Br J Psychiatry 1996;168:516–18 Jibson MD, Tandon R. New atypical antipsychotic medications. J Psychiatric Res 1998;32:215–28 Meltzer HY. Pharmacologic treatment of negative symptoms. In Greden JF, Tandon R, eds. Negative Schizophrenic Symptoms: Pathophysiology and Clinical
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Implications. Washington, DC: American Psychiatric Press, 1990:215–31 Tandon R, Ribeiro SC, DeQuardo JR, et al. Covariance of positive and negative symptoms during neuroleptic treatment in schizophrenia: a replication. Biol Psychiatry 1993;34:495–7 Hagger C, Buckley P, Kenny JT, et al. Improvement in cognitive functions and psychiatric symptoms in treatment refractory schizophrenic patients receiving clozapine. Biol Psychiatry 1993;34:702–12 Breier A, Buchanan RW, Kirkpatrick B, et al. Effects of clozapine on positive and negative symptoms in outpatients with schizophrenia. Am J Psychiatry 1994;151:20–6 Conley R, Gounaris C, Tamminga C. Clozapine response varies in deficit versus non-deficit schizophrenic subjects. Biol Psychiatry 1994;35:746–7 Kane JM, Safferman AZ, Pollack S, et al. Clozapine, negative symptoms, and extrapyramidal side effects. J Clin Psychiatry 1994;55(9, suppl B):74–7 Carpenter WT Jr. Maintainence therapy of persons with schizophrenia. J Clin Psychiatry 1996;57 (Suppl. 9):10–18 Tollefson GD, Beasley CM Jr, Tran PV, Street JS. Olanzapine versus haloperidol in the treatment of schizophrenia and schizoaffective and schizophreniform disorders: results of an international collaborative trial [see comments]. Am J Psychiatry 1997;154:457–65 Danion JM, Rein W, Fleurot O. Improvement of schizophrenic patients with primary negative symptoms treated with amisulpride. Amisulpride Study Group. Am J Psychiatry 1999;156:610–6 Boyer P, Lecrubier Y, Puech AJ, et al. Treatment of negative symptoms in schizophrenia with amisulpride. Br J Psychiatry 1995;166:68–72 Paillere-Martinot ML, Lecrubier Y, Martinot JL, Aubin F. Improvement of some schizophrenic deficit symptoms with low doses of amisulpride. Am J Psychiatry 1995;152:130–4 Speller JC, Barnes TR, Curson DA, et al. One-year, low-dose neuroleptic study of in-patients with chronic schizophrenia characterised by persistent negative symptoms. Amisulpride v. haloperidol. Br J Psychiatry 1997;171:564–8 Meltzer HY, Thompson PA, Lee MA, Ranjan R. Neuropsychologic deficits in schizophrenia: relation to social function and effect of antipsychotic drug treatment. Neuropsychopharmacology 1996;14(Suppl 3):27S–33S Bilder RM. Neurocognitive impairment in schizophrenia and how it affects treatment options. Can J Psychiatry – Revue Can Psychiatrie 1997;42: 255–64
100. Lee MA, Thompson PA, Meltzer HY. Effects of clozapine on cognitive function in schizophrenia. [Review]. J Clin Psychiatry 1994;55(Suppl B):82–7 101. Gallhofer B, Bauer U, Lis S, et al. Cognitive dysfunction in schizophrenia:comparison of treatment with atypical antipsychotic agents and conventional neuroleptic drugs. Eur Neuropsychopharmacol 1996;6(Suppl. 2):S13–20 102. Green MF, Marshall BD, Jr., Wirshing WC, et al. Does risperidone improve verbal working memory in treatment-resistant schizophrenia? Am J Psychiatry 1997;154:799–804 103. McGurk SR, Meltzer HY. The effects of atypical antipsychotic drugs on cognitive functioning in schizophrenia. Schizophrenia Res 1998;29:160 104. Sax KW, Strakowski SM, Keck PE Jr. Attentional improvement following quetiapine fumarate treatment in schizophrenia. Schizophr Res 1998;33:151–5 105. Peretti CS, Danion JM, Kauffmann-Muller F, et al. Effects of haloperidol and amisulpride on motor and cognitive skill learning in healthy volunteers. Psychopharmacology 1997;131:329–38 106. Zarate CAJ, Tohen M, Banov MD, et al. Is clozapine a mood stabilizer? J Clin Psychiatry 1995;56:108–12 107. Kimmel SE, Calabrese JR, Woyshville MJ, Meltzer HY. Clozapine in treatment-refractory mood disorders [Review]. J Clin Psychiatry 1994;55(Suppl B):91–3 108. Calabrese JR, Kimmel SE, Woyshville MJ, et al. Clozapine for treatment-refractory mania. Am J Psychiatry 1996;156:759–64 109. Meltzer HY, Okayli G. Reduction of suicidility during clozapine treatment of neuroleptic-resistant
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schizophrenia: impact on risk benefit assessment. Am J Psychiatry 1995;152:183–90 Banov MD, Zarate CAJ, Tohen M, et al. Clozapine therapy in refractory affective disorders: polarity predicts response in long term follow up. J Clin Psychiatry 1994;55:295–300 Rothschild AJ. Management of psychotic, treatment resistant depression. Psychiatr Clin North Am 1996; 19:237–52 Tollefson GD, Sanger TM, Lu Y, Thieme ME. Depressive signs and symptoms in schizophrenia: a prospective blinded trial of olanzapine and haloperidol [published erratum appears in Arch Gen Psychiatry 1998;55:1052]. Arch Gen Psychiatry 1998;55:250–8 Lecrubier Y, Boyer P, Turjanski S, Rein W. Amisulpride versus imipramine and placebo in dysthymia and major depression. Amisulpride Study Group. J Affect Dis 1997;43:95–103 Geddes J, Freemantle N, Harrison P, Bebbington P. Atypical antipsychotics in the treatment of schizophrenia: systematic overview and meta-regression analysis. [see comments]. Br Med J 2000;321:1371–6 Kapur S, Remington G. Atypical antipsychotics. [letter]. Br Med J 2000;321:1360–1 Prior C, Clements J, Rowett M, et al. Atypical antipsychotics in the treatment of schizophrenia. Br Med J 2001;322:924 Taylor, D. Low dose typical antipsychotics – a brief evaluation. Psychiatr Bull 2000;24:465–8 Arranz MJ, Munro J, Birkett J, et al. Pharmacogenetic prediction of clozapine response. Lancet 2000;355: 1615–6
CHAPTER
5
Psychosocial management
It is obvious that the successful management of schizophrenia requires careful attention to much more than just pharmacology. All good clinicians spend a large proportion of their time dealing with issues that can broadly be described as ‘psychosocial’. However, because it is very difficult to distill the relevant psychosocial issues down to a set of rigorously evaluable interventions, this important aspect of treatment is under-researched and relatively unacknowledged. Research into specific areas of psychosocial management falls into two main categories: the effectiveness of individual psychological therapies, and the optimal organization of mental health services. Research in both areas suffers from the perennial methodological difficulties of adequate control groups and statistical power, and from questions over the extent to which one can generalize from small research settings to large-scale clinical implementation. Nevertheless, psychosocial interventions have become increasingly prominent components of health policy1.
Cognitive behavioral therapy Cognitive behavioral therapy (CBT) encompasses a variety of interventions. At its core is the idea that if patients can be presented with a credible ‘cognitive’ model of their symptoms, they may develop more adaptive coping strategies, leading to reduced distress, improved social function and possibly even symptom reduction. CBT involves regular one-to-one contact over a defined time period between patient and therapist, the latter often (but not always) a clinical psychologist (other professionals including community psychiatric nurses and psychiatrists are becoming increasingly involved as trained therapists) (Figure 5.1). The treatment packages emphasize engagement and insight, and devote considerable
PSYCHOLOGICAL THERAPIES Psychoanalytic psychotherapies have largely been discredited in the management of schizophrenia, and indeed cast something of a shadow over the development of more effective approaches to treatment. However, a number of very promising new approaches are now emerging.
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Figure 5.1 Professor Elizabeth Kuipers, one of the pioneers of cognitive behavioral therapy (CBT) for psychosis, treating a ‘patient’ [played here by a colleague]
CHANGE IN DELUSIONAL VARIABLES
Distress
Conviction
Preoccupation
Change in score
0.0
–0.5
–1.0
–1.5
–2.0
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Control
NON-COMPLIANCE: THE PATIENTS' PERSPECTIVE
60
Responders (%)
50 40 30 20
Figure 5.2 Sixty patients with chronic schizophrenia were randomized to nine months of cognitive behavioral therapy (CBT) and standard care, or standard care alone. At 18 months, patients with delusions who had received CBT were found to hold these with a reduced level of conviction, and were less preoccupied and distressed by their delusional beliefs. Figure reproduced with permission from Kuipers E, Garety P, Fowler D, et al. The London-East Anglia randomised controlled trial of cognitivebehavioural therapy for psychosis: III. Follow-up and economic evaluation at 18 months. Br J Psychiatry 173:61–8
Figure 5.3 Over half of a group of 615 patients admitted to having stopped their medication. Figure reproduced with kind permission from Hellewell, JSE. Antipsychotic tolerability: the attitudes and perceptions of medical professionals, patients and caregivers towards the side effects of antipsychotic therapy. Euro Neuropsychopharmacol 1998;8:S248
10 0
Admitted stopping taking medication
Compliant with medication
attention to agreeing a common therapeutic agenda. Relatively non-specific elements form an important component of all treatment packages, including basic information about schizophrenia and its drug treatment, strategies to manage associated anxiety and depression, and interventions to tackle negative symptoms and social function. More specific strategies to target positive symptoms include formulating, together with the
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No answer
patient, alternative, more adaptive explanatory models for delusions and hallucinations. There are, however, substantial differences of detail between published studies, for example with respect to the duration of the intervention, or the incorporation of family work. A distinction is also made between CBT for acute and for chronic schizophrenia, although results are encouraging in both contexts (Figure 5.2)2–5. However, at the
THE MAIN REASONS FOR NON-COMPLIANCE
80
Responders (%)
60
40
20
Figure 5.4 The views of psychiatrists and nurses on the main reasons for patients’ noncompliance with medication. Both groups underestimate the importance of sexual side-effects, the psychiatrists more so than the nurses. Figure reproduced with kind permission from Hellewell, JSE. Antipsychotic tolerability: the attitudes and perceptions of medical professionals, patients and caregivers towards the side effects of antipsychotic therapy. Euro Neuropsychopharmacol 1998;8:S248
0
Psychiatrists
Nurses
Extrapyramidal side-effects
Weight gain
Side-effects in general
Sexual dysfunction
Lack of patient insight
time of writing, the published data do not exclude the possibility that many of the beneficial effects may arise from non-specific factors, such as befriending and increased contact time with the therapist.
Neurocognitive remediation Neurocognitive remediation attempts to improve cognitive function, and thereby influence symptoms and functional outcome for the better through task practise and repetition. Cognitive function is a key determinant of long-term outcome in schizophrenia6, but to date, the clinical results of interventions focusing on specific cognitive deficits have been disappointing. At a more practical level, vocational rehabilitation and social skills training remain important elements of many treatment programmes with a focus on rehabilitation and functional outcome.
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Compliance with drug treatment This is another important determinant of outcome in schizophrenia, since the majority of patients admit to stopping their medication at some stage (Figure 5.3). The latter is hardly surprising, since they are asked to take drugs with unpleasant sideeffects, including extrapyramidal symptoms, weight gain and sexual dysfunction (Figure 5.4) for long periods of time. Few psychiatrists stop to think whether they themselves would be 100% compliant in taking regular medication in the face of such side-effects. Compliance therapy7 uses simple psychological interventions focusing on the psychological aspects of long-term drug treatment in schizophrenia, emphasising insight and the formation of a therapeutic alliance between prescriber and patient, and appears to be effective and relatively straightforward to incorporate into routine practice.
EXPRESSED EMOTION IN SCHIZOPHRENIA
Total (n = 128) 30%
High (n = 57) 51%
Emotional expression
Weekly contact
Drug maintenance
More than 35 hours 69%
Nil 92%
Full 53%
Low (n = 71) 13%
Figure 5.5 This figure shows the results of a trial of maintenance antipsychotics in patients divided according to whether their families showed high expressed emotion (EE) or not. The degree of EE in families predicts relapse in patients with schizophrenia who are not taking antipsychotic drugs, and who are in contact with their familites for more than 35 hours each week
Less than 35 hours 28%
Nil 42%
Full 15%
Nil 15%
Full 12%
Family treatments
Early intervention
It has long been recognised that high levels of ‘expressed emotion’ (EE) in the family increase the risk of relapse in unmedicated patients (Figure 5.5). The question then arose whether psychological interventions with the families of schizophrenic patients might have any effect on this. Family therapy in schizophrenia is based on a ‘psycho-educational’ approach which includes information about the nature of the disorder, its treatment, and factors (including EE) which might modify its course. It appears to have a modest effect in reducing the risk of relapse in schizophrenia8, although this may not in fact be directly mediated through a specific effect on EE. Another important source of family input exists in the voluntary sector, where groups such as (in the UK) the National Schizophrenia Fellowship can be extremely helpful in providing support and information for the relatives and carers of people with schizophrenia.
Much interest has recently focused on the treatment of schizophrenia early in the first episode of illness. The impetus behind this is preventative: many studies have shown a mean duration of untreated psychosis of the order of one year. Underlying this is a bimodal distribution: people with florid psychosis often present fairly rapidly, particularly if their symptoms bring them into conflict with families or wider society, but others with more insiduously-developing illnesses can take many years to come to psychiatric attention. It is argued that the early stages of illness represent an opportunity for intervention which may modify its long-term course and minimize the degree of residual disability9. For early intervention to succeed, the repertoire of psychosocial interventions in schizophrenia must include public education, improving referral pathways from primary care, and challenging stigmatizing and discriminatory attitudes to people with
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0.14
30,000
0.12
25,000
0.10
20,000
0.08 15,000 0.06 10,000
0.04
5000
0.02
–7 96
19
95
–6
–5 19
94
–4
19
93
–3 19
92
–2 19
91
–1 19
90 19
–9
0
–9
89 19
88
–8 19
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86
19
19
19
19
85
0 84
0
Total compulsory admissions
Proportion of all admissions that were compulsory
COMPULSORY PSYCHIATRIC ADMISSIONS IN ENGLAND: 1984–1996
Year of admission Figure 5.6 Despite the policy of care in the community there was a rise in total admissions between 1984 and 1996, and a rise in the proportion of compulsory admissions. A combination of increased prevalence of comorbid drug misuse, reductions in available bed numbers (a reduction of 43 000 in the UK between 1982 and 1992), and changes in the thresholds for admission and discharge, has meant that patients are more severely ill before admission, and services are under greater pressure, leading to a paradoxical increase in the use of compulsory detention. (Bars represent the total number of compulsory psychiatric admissions to NHS facilities and the line represents the proportion of all admissions that were compulsory in England, 1984–96. Data on compulsory admissions not available for 1987–89). Figure reproduced with permission from Wall S, Hotopf M, Wessely S, Churchill R. Trends in the use of the Mental Health Act, England 1984–1996. Br Med J 1999;318:1520–1
schizophrenia which act as disincentives to early referral and treatment.
Managing schizophrenia in the community The move toward treating people with schizophrenia in the community (Figures 1.15 and 5.6) was made possible (both clinically and politically), from the 1950s onwards, by the introduction of effective antipsychotic drugs. The purpose of this was to give patients with psychosis a better quality of life, and there is no doubt that patients generally prefer to be treated in their own home rather than in hospital (Figure 5.7). However, since drug treatment was so crucial to the move towards community care, the delivery and monitoring of
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medication became a major preoccupation of the organizational systems that developed to support it. A second priority, intermittently reinforced by clinical scandal and catastrophe, has been the assessment and management of the risks, both perceived and real, associated with the shift of care away from the relatively secure and contained environment of the hospital ward. Thirdly, the new community mental health teams needed to lubricate the interactions between their ill and sometimes institutionalized patients and the complex bureaucracies – housing, social security, the judicial system, employers – of the outside world. However, none of this should distract us from the objective of delivering better care, and the awareness that good care involves more than simply drug treatment.
Figure 5.7 Prior to the 1950s and the introduction of effective antipsychotic treatment, most patients with schizophrenia would have been institutionalized in largescale psychiatric hospitals. This painting from 1843 shows one such hospital in Gartnavel, Glasgow, UK
Figure 5.8 An international study of pyschiatrists’ attitudes to community care. Note that the countries in which psychiatrists have the most positive attitudes, Switzerland, Denmark, The Netherlands and Germany, have the highest per capita spending on mental health services
ASSESSMENT OF CARE IN THE COMMUNITY
Switzerland Sweden Denmark Netherlands Spain Italy Germany France UK 0%
20%
40%
60%
Percentage of doctors adequate
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poor
80%
100%
Various models have evolved in the face of these demands. These are mostly based on variations of ‘case management’, in which mental health workers take responsibility for the planning, co-ordination, review, and to varying extents the delivery of care ‘packages’ to individual patients. In practise, most services organized on these principles have developed eclectic and pragmatic ways of working, which have proved at least as effective as more hospital-based models of clinical care10. The formal models differ in their specifics, for example in the precise role of the keyworker, caseload, organizational philosophy, and specialist functions, such as assertive outreach and crisis intervention. The benefit of one approach over any other remains a matter of debate (see for example reference 11). In any event, such organizational models should not be confused with treatments, and their clinical impact on specific symptoms is likely to be indirect and less pronounced than their effect on more general social variables such as housing stability. Comparisons between different approaches to the organization of community psychiatric care are made more difficult by wide variations internationally in clinical practice and in resources, and there are wide international differences in the extent to which community care is regarded as a successful policy (Figure 5.8)14.
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Drury V, Birchwood M, Cochrane R, MacMillan F. Cognitive therapy and recovery from acute psychosis: II. Impact on recovery time. Br J Psychiatry 1996;169:602–7 Kuipers E, Garety P, Fowler D, et al. The LondonEast Anglia randomised controlled trial of cognitivebehavioural therapy for psychosis: III. Follow-up and economic evaluation at 18 months. Br J Psychiatry 1998;173:61–8 Tarrier N, Yusupoff L, et al. Randomised controlled trial of intensive cognitive behaviour therapy for patients with chronic schizophrenia. Br Med J 1998; 317:303–7 Green MF. What are the functional consequences of neurocognitive deficits in schizophrenia? Am J Psychiatry 1996;153:321–30 Kemp R, Hayward P, et al. Compliance therapy in psychotic patients: a randomised controlled trial. Br Med J 1996;312:345–9 Pharoah FM, Mari JJ, Streiner D. Family intervention for schizophrenia (Cochrane Review). In The Cochrane Library. Oxford: Update Software, 1999: issue 3 Birchwood M, Todd P, Jackson C. Early intervention in psychosis: the critical-period hypothesis. Int Clin Psychopharm 1998;13(Suppl 1):S31–S40 Tyrer P, Coid J, Simmonds S, et al. Community mental health teams for people with severe mental illnesses and disordered personality (Cochrane Review). In The Cochrane Library. Oxford: Update Software, 1999:issue 3 Burns T, Creed F, et al. Intensive versus standard case management for severe psychotic illness: a randomised trial. Lancet 1999;353:2185–9 Mueser KT, Bond GR, Drake RE, Resnick SG. Models of community care for severe mental illness: a review of research on case management. Schizophr Bull 1998;24:37–74 Wall S, Hotopf M, Wessely S, Churchill R. Trends in the use of the Mental Health Act, England 19841996. Br Med J 1999;318:1520–1 Smith-Latten, Grimdy S. Survey of European Psychiatrists. London: Martin Hamlyn